Evaluation and Policy for Bridge Deck Expansion Joints
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FHWA/IN/JTRP-2000/1 Final Report EVALUATION AND POLICY FOR BRIDGE DECK EXPANSION JOINTS
Luh-Maan Chang Yao-Jong Lee
February 2001
Final Report
FHWA/IN/JTRP-2000/1
EVALUATION AND POLICY FOR BRIDGE DECK EXPANSION JOINTS
By
Luh-Maan Chang Principal Investigator
Yao-Jong Lee
Research Assistant
and
School of Civil Engineering Purdue University
Joint Transportation Research Program
Project No: C-36-56UU File No: 7-4-46
SPR-2198
In cooperation with the Indiana Department of Transportation
and the Federal Highway Administration
The contents of this report reflect the views of the authors, who are responsible for the facts and the accuracy of the data presented herein. The contents do not necessarily reflect the views or policies of the Federal Highway Administration and the Indiana Department of Transportation. This report does not constitute a standard, specification, or regulation.
Purdue University West Lafayette, IN 47907
February 2001
25-1 2/01 JTRP-2000/1 INDOT Division of Research West Lafayette, IN 47906
INDOT Research
TECHNICAL Summary Technology Transfer and Project Implementation Information
TRB Subject Code: 25-1 Bridge Design and Performance February 2001 Publication No.: FHWA/IN/JTRP-2000/1, SPR-2198 Final Report
Evaluation and Policy for Bridge Deck Expansion Joints
Introduction To continuously improve the performance of
expansion bridge deck joints on Indiana Department of Transportation (INDOT) bridges prompted this research. The performances of
several types of joints were investigated through questionnaire surveys, expert interviews, analysis of INDOT historical data, and site assessment.
Findings This research focused on five types of
joints: Compression Seal (B.S.) joint, Strip Seal (S.S.) joint, Poured Silicone (XJS) joint, Integral Abutment Jointless (I.A.) joint, and Polymer Modified Asphalt (LDI and PaveTech) joint. The findings are listed as follows: 1. The problems and their causes, the merits,
the potential improvements, and the estimated lives of these types of joints were identified from the questionnaire surveys. The results show that the S.S., B.S., and I.A. joints are rated as the top three for their longer estimated lives, as well as other attributes.
2. The results of the factor and logistic
regression analyses of the INDOT Roadway Management data indicate that the S.S., B.S., and I.A. joints are ranked first, second, and third respectively for their
performance. The ranking is based on deterioration rates under identical conditions of traffic loading, settlement, and age. The performance of other types of joints could not be rated due to insufficient data.
3. The investigation of the practices of
surrounding states revealed that each state has its own experiences in using and maintaining the bridge deck expansion joints. There are no uniform specifications, drawings, and maintenance strategies among the investigated states. The investigation also found that the Integral Abutment Expansion joint (I.A.) is being commonly used in the surrounding states.
4. Based on the research findings, a more
objective evaluation method was developed for inspecting bridge deck expansion joints.
Implementation This research generates several
recommendations for implementation. They are as follows: 1. From the research result, S.S. and I.A. joints
were shown to have better performances and
are thus recommended to be continually used. The B.S. joint could perform well if materials such as seals are properly selected and the installation correctly done. The XJS joint needs to be evaluated for its long-term performance.
25-1 2/01 JTRP-2000/1 INDOT Division of Research West Lafayette, IN 47906
2. If Polymer Modified Asphalt joints are used, caution should be taken to use them in locations where there is less truck traffic and bridge movement is small.
3. Many joint problems resulted from steel and
concrete. Concrete needs to be protected by sealers and the plate and bars holding the seal need to be more corrosion-resistant.
4. To hold contractors accountable, the implementation of warranty clauses in the contract is recommended, which could also enhance the quality of expansion joints installed.
5. The proposed expansion joint condition
rating schemes are more objective and ready for use.
Contacts For more information: Prof. Luh-Maan Chang Principal Investigator School of Civil Engineering Purdue University West Lafayette IN 47907 Phone: (765) 494-2246 Fax: (765) 494-0644
Indiana Department of Transportation Division of Research 1205 Montgomery Street P.O. Box 2279 West Lafayette, IN 47906 Phone: (765) 463-1521 Fax: (765) 497-1665 Purdue University Joint Transportation Research Program School of Civil Engineering West Lafayette, IN 47907-1284 Phone: (765) 494-9310 Fax: (765) 496-1105
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TABLE OF CONTENTS
ABSTRACT i LIST OF TABLES iv LIST OF FIGURES v CHAPTER 1 INTRODUCTION 1
1.1 Problem Statement 1
1.2 Purpose and Objectives 2
CHAPTER 2 BACKGROUND 4
2.1 Types of Joints 4
2.2 Joints Investigated in the Research 8
2.3 Successful Performance of Expansion Joints 13
2.4 Deterioration Indicators 13
CHAPTER 3 METHODOLOGY 15 CHAPTER 4 LITERATURE REVIEW 18 CHAPTER 5 QUESTIONNAIRE SURVEY 22
5.1 Introduction 22
5.2 Analysis of the First and Second Survey Data 23
5.3 Implementation of the First and Second Questionnaire Survey 25
5.4 Discussion of Findings from the First and Second Questionnaire Survey 26
5.5 Follow-up Survey 34
5.6 Summary 36
CHAPTER 6 IN-STATE SITE VISITS 39 CHAPTER 7 EXPERT INTERVIEWS 43
7.1 In-State Interviews 43
7.2 Surrounding States Interviews 45
7.3 Summary 48
CHAPTER 8 ESTABLISH EVALUATION CRITERIA/SCHEMES 51
8.1 Current Practices of Evaluating Existing Expansion Joints 51
8.2 Proposed New Evaluation Schemes 51
iii
CHAPTER 9 DATA ANALYSIS 58
9.1 Simple Statistics 58
9.2 Regression Analysis 63
9.3 Summary 71
CHAPTER 10 GUIDELINE OF POLICY DEVELOPMENT 73
10.1 Selection of the Bridge Deck Expansion Joints 73
10.2 Evaluation of the Existing Joint Conditions 74
10.3 Improvement of the Joint Performance 75
CHAPTER 11 CONCLUSION 78
11.1 Results 78
11.2 Limitations 81
11.3 Recommendations and Implementation for Future Work 82
REFERENCES 85
APPENDIX
Appendix A Questionnaire of the First Survey
Appendix B Result of the First Survey
Appendix C Questionnaire of the Second Survey
Appendix D Result of the Second Survey
Appendix E Numerical Example of Survey Data Analysis
Appendix F Questionnaire and Result of the Follow-up Survey
Appendix G Pictures of the In-State Site Visits
Appendix H Statistics of Joint Data in Each Indiana District
Appendix I Computer SAS Code and Output of Regression Analysis
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TECHNICAL REPORT STANDARD TITLE PAGE 1. Report No.
2. Government Accession No.
3. Recipient's Catalog No.
FHWA/IN/JTRP-2000/1
4. Title and Subtitle Evaluation and Policy for Bridge Deck Expansion Joints
5. Report Date February 2001
6. Performing Organization Code 7. Author(s) Luh-Maan Chang and Yao-Jong Lee
8. Performing Organization Report No. FHWA/IN/JTRP-2000/1
9. Performing Organization Name and Address Joint Transportation Research Program 1284 Civil Engineering Building Purdue University West Lafayette, Indiana 47907-1284
10. Work Unit No.
11. Contract or Grant No. SPR-2198
12. Sponsoring Agency Name and Address Indiana Department of Transportation State Office Building 100 North Senate Avenue Indianapolis, IN 46204
13. Type of Report and Period Covered
Final Report
14. Sponsoring Agency Code
15. Supplementary Notes Prepared in cooperation with the Indiana Department of Transportation and Federal Highway Administration. 16. Abstract This report is an overview of the research that was performed for the Indiana Department of Transportation (INDOT) concerning the performance of bridge deck expansion joints. The purpose of the research is to evaluate several types of joints currently in use and also provides the evaluation criteria for rating the joint condition. The types of joints investigated are Compression Seal (B.S.) joint, Strip Seal (S.S.) joint, Integral Abutment Jointless (I.A.) joint, Poured Silicone (XJS) joint, and Polymer Modified Asphalt (LDI and PaveTech) joint. The research was performed by questionnaire surveys, Roadway Management data analysis, expert interviews, and site assessment. The problems and their causes, the merits, the potential improvements, and the estimated lives of these types of joints were identified from the questionnaire surveys. The results showed that the S.S., B.S., and I.A. joints are rated as the top three for their longer estimated lives as well as other attributes The results of the factor and logistic regression analyses of the INDOT Roadway Management data indicate that the performances of the S.S., B.S., and I.A. joint are rated first, second, and third respectively, based on deterioration rates under identical conditions of traffic loading, settlement, and age. Other types of joints could not be analyzed due to insufficient data. The investigation of the practices of surrounding states revealed that each state has its own experiences in using and maintaining the joints. There are no uniform drawings, specifications, and maintenance strategies among the investigated states. The investigation also showed that the Integral Abutment Expansion joint (I.A.) is commonly being used in the surrounding states. Finally the research provides pilot evaluation schemes for inspecting joints. Based on the findings of this research, an implementation policy has been designed to ensure the longer service life of expansion joints. 17. Key Words Expansion joint, Logistic regression, Odds ratio, Factor analysis
18. Distribution Statement No restrictions. This document is available to the public through the National Technical Information Service, Springfield, VA 22161
19. Security Classif. (of this report)
Unclassified
20. Security Classif. (of this page)
Unclassified
21. No. of Pages
173
22. Price
Form DOT F 1700.7 (8-69)
iv
LIST OF TABLES Table Page Table 2.1 Types of Joints Studied in this Research 8
Table 2.2 Bridge Joint Data on INDOT Bridges – minus Toll Road 9
Table 2.3 Summary of Features, Advantages, Disadvantages of Each Type of Joint 11
Table 5.1 Number of Questionnaires Issued and Returned 25
Table 5.2 Methodology for Ranking Overall Joint Problems 30
Table 5.3 Overall Ranking of Joint Problems (First Survey) 31
Table 5.4 Estimated Joint Life (Survey #1) 33
Table 5.5 Estimated Joint Life (Survey #2) 33
Table 5.6 Recommend Types of Joints 34
Table 5.7 Performance of Joints based on Riding Quality, Water Leakage, Noise, 35 and Difficult of Maintenance
Table 8.1 B.S. Joint Evaluation Scheme 53
Table 8.2 S.S. Joint Evaluation Scheme 54
Table 8.3 I.A. Joint Evaluation Scheme 55
Table 8.4 XJS Joint Evaluation Scheme 56
Table 8.5 Polymer Modified Asphalt Joint Evaluation Scheme 57
Table 9.1 Joint Number Statistics 58
Table 9.2 Simple Statistics of Joint Data 59
Table 9.3 Comparison of Joint Types and Conditions at Both Ends of Bridge 62
Table 9.4 Percentage Distribution of Joint Conditions 62
Table 9.5 Variables Selected for the Regression Analysis 64
Table 9.6 Variables Selected by Simple Regression Analysis 65
Table 9.7 Factor Analysis Result 67
Table 9.8 Logistic Regression Analysis Result 68
Table 9.9 Joint Ranking based on the Deterioration Rate 72
Table 11.1 Estimated Life of Each Type of Joint 79
Table 11.2 Summarized Ranking for Recommended Types of Joints 79
Table 11.3 Performance of Joints based on Specific Categories 80
Table 11.4 Joint Ranking based on the Deterioration Rate 80
v
LIST OF FIGURES
Figure Page
Figure 3.1 Research Methodology 17
Figure 9.1 Percentage Distribution of Joint Conditions 61
Figure 9.2 Performance Curve based on Age 70
Figure 9.3 Performance Curve based on Traffic Loading 70
Figure 9.4 Performance Curve based on Settlement 71
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CHAPTER 1
INTRODUCTION
1.1 Problem Statement
Bridge deck expansion joints are among the smaller elements of a bridge structure, but
when they fail to function properly, joints can create problems out of proportion to their
size. The potential for developing serious structural problems comes from the expansion
joint’s role in accommodating necessary structural movements of the bridge elements.
Whenever the expansion join system becomes unable to accommodate the movement, the
bridge elements experience over-stress that may eventually result in damage to those
elements and/or the expansion joints themselves.
It is important to appreciate that expansion joints are located in the most vulnerable
position possible on any bridge. Situated at surface level, the expansion joints are subject
to the impact and vibration of traffic and exposed not only to the effects of natural
elements such as water, dust, grit, UV rays, and ozone, but also those of applied
chemicals such as salt solutions, cement alkalis, and petroleum derivatives. All the
aforementioned external effects can cause a severe deterioration phenomenon within the
various bridge elements, which is presumably protected by the expansion joints, if the
existing system fails to perform properly. It is not uncommon to notice seriously
deteriorated spots beneath the deck expansion joints of both steel and concrete bridges.
A survey of 200 concrete bridges identified leaking expansion joints, poor or faulty
drainage detail, defective or ineffective waterproofing, and limited access to bearing
shelves as being major factors in the deterioration of those structures (Department of
Transportation, London, 1989).
The results of an improper expansion joint system can be extremely expensive.
However, if the expansion joint is carefully designed and detailed, properly installed by
specialists and functioning, and given reasonable maintenance in service, there is no
reason why it should not give trouble-free performance for its lifetime. Today, there are
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a large number of proprietary expansion joints on the market and the problem facing the
engineer is often that of selecting the most suitable joint to give good performance and a
trouble-free life for at least as long as that of the surfacing material. This decision is by
no means an easy one to make, especially with the inclusion of various technical and
financial parameters (Brinckerhoff, 1993; and Lee, 1994).
1.2 Purpose and Objectives
The most important objective was to determine the reason for failure and the short life
span of the expansion joints. This was further investigated by observing the practices of
surrounding states that may have better expansion joint performance than INDOT. The
observation was done by acknowledging the types of joints used and when they are used.
Also the maintenance and aging of existing joints was observed and compared to the
current INDOT practice in detail to determine what differences may exist.
The purpose of this research was to develop a reliable evaluation system for assessing
various bridge deck expansion joints and to establish a corresponding policy. The policy
is aimed at assisting INDOT personnel to assure that the put-in-place expansion joints
will have the capacity of accommodating up to 4” movements and at least have 10 years
service life.
To accomplish the above purpose, the following objectives needed to be achieved
accordingly.
1. To investigate the critical parameters attributing to the poor and successful
performance of expansion joint systems currently used by INDOT.
2. To identify the expansion joint systems that have a successful in-service performance
record in Indiana and surrounding states.
3. To construct reliable evaluation criteria for assessing expansion joint systems that are
either put in place or available on the market.
3
4. To perform in-service performance verification on the identified expansion joint
system.
5. To supply the framework for a policy that INDOT can use for selecting and
evaluating expansion joint systems.
4
CHPATER 2
BACKGROUND
A deck joint, depending on the type of movement it accommodates, can be classified as
fixed or expansion. A fixed expansion joint allows only rotation, whereas an expansion
joint may accommodate all required movements (longitudinal, transverse, and rotational).
Several expansion joint systems are currently available on market. The list includes:
open joints, filled joints (field-formed joint sealers/pre-formed joint sealers), compression
seal joints, sliding plate joints, finger plate joints, saw-tooth plate joints, strip seal joints,
sheet seal joints, modular joints, Jeene system joints, etc. Some of the aforementioned
systems are presented in greater detail in the following sections (Brinckerhoff, 1993).
2.1 Types of Joints
2.1.1 Filled Joints (Field-Formed Sealers/Pre-Formed Sealers)
A filled joint is an open joint filled and sealed with a flexible and compressible material.
Filled joints are inexpensive and easy to install and maintain. As a result, they have
enjoyed widespread use in bridges. They are frequently encountered in existing bridges
and in deck joint rehabilitation projects. The joint sealers, depending on the manner in
which they are applied, are classified as field-formed, which are useful for movements up
to 1 inch, or preformed useful up to 4 inches.
Field-formed joint sealers are commonly composed of hot applied thermoplastics or
chemically cured thermosetting sealants. Application of a field-formed joint sealer
requires a pre-formed backup material and water stop beneath it to control the sealer
depth and shape, and at the same time provide support to the sealer. Pre-formed sealers
are somewhat newer and hence have a shorter record of proven service than field-formed
sealers. An important advantage they offer is quick installation time and less interruption
to traffic. Most commonly used types of pre-formed sealers for deck expansion joint
rehabilitation projects are extruded shapes made of elastomeric material.
5
The types of joints currently in use by INDOT belonging to this type are Poured Dow
Corning Silicone Joint (XJS), PaveTech Joint, and Polymer Modified Asphalt Expansion
Joint.
2.1.2 Sliding Plate Joints
Sliding plate joints are frequently encountered in existing medium-span bridges, and they
continue to be used in new bridges and the rehabilitation of existing deck joints. Most of
the existing sliding plate joints were constructed without any joint drainage system since
the joint itself was considered to restrict the amount of infiltrating water to a minimum.
The joint does not, however, completely eliminate the intrusion of water. Therefore, in
recent systems, a trough is often supplemented to the plate system for long-term
protection of the surrounding bridge components. The sliding plate joint features a steel
plate spanning an open joint and embedded in adjoining deck slabs. It can also be
arranged to bear on the steel structure itself.
2.1.3 Finger (Tooth) Plate Joint
Finger plate joints have been successfully used in medium- and long-span bridges for
some time. They continue to be a popular option for new medium- and long-span bridges
or in deck joint rehabilitation projects, as they are able to accommodate relatively large
movements. Typical finger plate joints are made up of two loosely interlocking pieces of
steel plates that cantilever into the deck joint opening. The cantilevered portion of each
plate is made up of rows of finger-shaped protrusions that fit into the rows of grooves in
the opposing plate. The finger plates are anchored into the deck slab or directly attached
to the underlying superstructure steel. In most existing finger plate joints, the water and
debris passing through the finger joint are collected and carried away by a trough system
similar to the one previously described.
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2.1.4 Compression Seal Joints
Compression seals are made of either pre-formed closed-cell plastic or, more commonly,
hollow extruded neoprene shapes. The seals are generally installed by squeezing and
inserting the seal into a pre-formed joint opening. Properly sized seals remain in
compression under all anticipated deck joint movements. To improve the water tightness
of the joint, the contract surfaces between the gap and seal are coated with a high-solids
urethane adhesive prior to the insertion of the compression seal into the joint opening.
The number of successful armored neoprene compression seal applications in the past
decades has made this type of seal probably the most popular one. Neoprene
compression sealers are available in a variety of configurations and movement ratings.
The largest size seal can accommodate a total movement of 4 inches.
2.1.5 Strip Seal Joints
Although strip seals were introduced for bridge use later than compression seals, they
have established a successful performance record. They continue to be a popular choice
in deck joint replacement projects. Strip seals, as the name implies, is a strip of specially
shaped elastomeric material that spans a deck joint opening. The seal is mechanically
locked into a pair of rolled or extruded metal shapes that are in turn anchored to the edges
of deck slabs. Strip seals are available in a number of configurations and a wide range of
movement ratings. The largest size strip seal can provide up to 5 inches of total
movement although most designers limit the total movement to 4 inches.
2.1.6 Sheet Seal Joints
Sheet seal is a sheet of fiber-reinforced elastomeric membrane with a center corrugation
that bridges a deck opening. At both ends, the seal is held down and anchored into the
corners of deck slabs by means of metal, elastomeric, or combination hold-down bar
(retainer bars) and anchor bolts. Similar to the strip seal, the sheet seal functions either in
tension or in compression and the deformation of the center corrugation accommodates
the deck slab movements. Sheet seals represent one of the possible choices for deck joint
7
replacement in existing medium-span bridges, and are available in a variety of shapes,
configurations, and sizes. A maximum of 4 inches of total movement is obtainable in a
sheet seal.
2.1.7 Plank Seal Joints
Plank seals are molded neoprene sections of varying widths. The seal spans the deck
opening and is bolted down to the deck slab at each end. A typical cross section displays
a number of grooves placed alternately on each face of the neoprene plank, with metal
plates spanning between these grooves. The checkered metal plates that are placed on the
roadway face of the seal improve the skid resistance and protect the seal against
snowplow damage or simple wear and tear. A plank seal accommodates the deck slab
movements by the closing and opening motions of the grooves in the blank surface. This
type of joint system, depending on the width of the plank and the number of grooves, can
allow total movements ranging from 1 21 to 13 inches.
2.1.8 Modular Joints
Modular joints represent the state-of-the-art approach to accommodating the complex
movements in long-span or curved bridges. Although the number of past applications is
not as numerous as single compression or strip seals, the success rate of modular joints,
particularly the ones with steel components, is encouraging. The modular joint system is
composed of three main components: sealer, separator beams (for sealers), and support
bars (for separator beams). Sealers can be of compression, strip, or sheet seal type.
Separator beams are often extruded or rolled metal shapes to provide for the joining of
seals in a series. The separator beams are supported on support beams at frequent
intervals. The modular joint system, because of its refined mechanical performance, can
accommodate the complex movements of long-span bridges as well as those of
horizontally curved bridges. The modular systems available on the market today can
provide total movements in the range of 4 feet.
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2.2 Joints Investigated in the Research
A detailed classification of the types of joints studied here is shown in Table 2.1. The
bridge joint data showing the types of joints currently in use and the total numbers of
each used on INDOT bridges (excluding Toll Roads) are listed in Table 2.2. A summary
of the features, advantages, and disadvantages of each type of joint is shown in Table 2.3.
Table 2.2 shows that B.S., S.S., and I.A. joints account for most of the joints currently in
use. XJS, LDI, and PaveTech joints are new and their performances are not well known.
Metal types of joints such as Tooth/Finger joints performed well in the past. Thus, the
Study Advisory Committee (SAC) decided to exclude metal types of joints and evaluate
B.S., S.S., I.A., XJS, LDI and PaveTech joints only in this research.
Table 2.1 Types of Joints Studied in this Research
Classification Joint Type Abbreviation
Compression Seal Joints Compression Seal B.S.
Strip Seal Joints Strip Seal S.S.
Jointless (Neoprene Seal) I.A.
Jointless (Poured Sealer) I.A.
Dow Corning Silicone XJS
Polymer Modified Asphalt
(manufactured by Linear
Dynamic Incorporation)
LDI
Filled Joints (Field-
formed Sealers/Pre-
formed Sealers)
Polymer Modified Asphalt
(manufactured by PaveTech) PaveTech
9
Table 2.2 Bridge Joint Data on INDOT Bridges – minus Toll Road
04/27/98
NUMBER OF BRIDGES BRIDGE JOINT TYPE
JOINT LOCATIONS
Code - Description SOUTH/WEST END
EAST/NORTH END
INTERIOR LOCATION
NO DATA LISTED YET 116 115 126
A = B.S. joint 1,855 1,873 415
B = S.S. joint 469 462 154
C = Tooth/Finger joint 34 34 11
D = General Tire jt. Trans Flex joint
20 18 9
E = Feldspar joint 2 2 1
F = Sliding Steel Plate jonit
51 53 12
G = Armor joint (2 Steel angles)
20 20 19
H = IA joint 918 909 34
I = Modular joint 25 43 24
J = Open Joint 73 71 2
K = No joint 935 939 80
L = Unknown/Covered 385 386 69
M = Structural Expansion Joint
116 109 44
N = N/A 11 10 4,205
10
NUMBER OF BRIDGES BRIDGE JOINT TYPE
JOINT LOCATIONS
Code - Description SOUTH/WEST END
EAST/NORTH END
INTERIOR LOCATION
O = Poured Dow Silicone joint (XJS joint)
52 51 10
P = Pave Tec joint 45 44 6
Q = Polymer Modified Asphalt Expan. Jt.
127 115 33
TOTALS 5,254 5,254 5,254
Table 2.3 Summary of Features, Advantages, and Disadvantages of Each Type of Joint
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Joint Type Open Joint Filled Joint Compression Seal Joint
Sliding Plate Joint Finger (Tooth) Plate Joint
Features Mostly encountered in old short-span bridges. The width of the joint is from 1/2 to 2 inches.
Encountered in most existing bridges. It can be classified as fieldformed, useful for movements up to 1 inch, or preformed, which is useful up to 4 inches.
The most popular joints. The largest size seal can provide for a total movement of 4 inches.
Frequently encountered in existing medium-span bridges. It can accommodate up to 4 inches of total movement.
Successfully used in medium- and long-span bridges. It can accommodate total movements from 4 to over 24 inches.
Advantages Initial construction cost is relatively low.
Inexpensive and easy to install and maintain. Fast installation time and less interruption to traffic.
A large variety of choices in movement ranges, watertightness, relative ease of installation, and cost effectiveness.
The joint itself was considered to restrict the amount of infiltrating water to a minimum.
It can accommodate relatively large movements.
Disadvantages Prone to the intrusion of deicing salts and water, creating costly repairs on surrounding bridge components in the long run.
It is newer and hence has a shorter record of proven service.
The success depends on the quality of the installation and the correct choice of the seal size and seal material. The compression seal may be ozone-sensitive.
A trough system is often needed beneath this type of joint for long-term protection of the surrounding bridge components.
Possible accumulation of debris and eventual clogging of the trough through the finger joint.
Table 2.3 Summary of Features, Advantages, and Disadvantages of Each Type of Joint
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Joint Type Sawtooth (Serrated) Plate Joint
Strip Seal Joint Sheet Seal Joint Plank Seal Joint Modular Joint
Features Encountered in existing medium span bridges. The movement can be in the range of 3 inches.
It has a successful performance record comparable with that of neoprene compression seals. The largest size strip can provide up to 5 inches of total movement.
The sheet seal can function either in tension or in compression. A maximum of 4 inches of total movement is easily obtainable.
An alternative for the replacement of existing joints in medium- and long-span bridges. It can allow total movements ranging from 1-1/2 to 13 inches.
It represents the state-of-the-art approach to accommodating the complex movements in long span or curved bridges. It can provide total movements in the range of 4 feet.
Advantages The direction changes can be easily achieved by welding the steel plates.
Perform better than the compression seal at locations in which transverse slab movements are anticipated and provide a superior seal against water leakage.
The ability to accommodate directional changes and skews in the joint configuration, often without any need for a splice in the seal.
The checkered metal plates that are placed on the roadway face of the seal improve the skid resistance and protect the seal against snowplow damage or simple wear and tear.
It provides large movements and also permits nonparallel horizontal movement, differential settlement, rotation, and high shearing movements.
Disadvantages Need to provide a trough system to collect water and debris.
The performance depends on the correct choice of seal size and seal material.
Failure of anchorage systems, under repetitive live-load impact, has been a frequently encountered problem.
Leakage at joints between segments, loose anchorages, excessive noise, and snowplow damage have been the problems commonly reported.
The noise under live-load impact, water leakage at seal splice locations, debris accumulation in seals, and snowplow damage.
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2.3 Successful Performance of Expansion Joints
To function properly, bridge expansion joints must satisfy the following conditions (Lee,
1994):
1. accommodate all movements of the structure, both horizontal and vertical;
2. withstand all applied loading;
3. have a good riding quality without causing inconvenience or hazards to any class of
road users;
4. not present a skid hazard;
5. be silent and vibration-free in operation;
6. resist corrosion and withstand attack from grit and chemicals;
7. require little or no maintenance;
8. allow easy inspection, maintenance, repair, or replacement.
The foregoing conditions could be considered as the evaluation criteria for selecting
suitable joints for bridges.
2.4 Deterioration Indicators
Although a deck joint system is often composed of a variety of materials (concrete, steel,
aluminum, copper, plastics, neoprene, epoxy, etc.) with different physical and chemical
properties, they all share a common fate: aging and deterioration. Starting with the day
they are installed, the deck expansion joints are continually exposed to both natural
elements and those introduced by humans. The combined effect of these elements on the
joint components is a steady and unavoidable deterioration process. Therefore, deck
expansion joint components should be carefully inspected to uncover the following
common defects (U.S. Department of Transportation, 1970):
1. Loose, torn, split, cracked, damaged, or hardened seals.
2. Accumulation of debris and incompressible materials in the seals, drainage troughs,
downspouts, and silting basins.
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3. Loose, rusted, cracked, missing, or damaged steel plates, shapes, anchorage, bolts,
nuts, and other metal components.
4. Cracked and spalled concrete, and rusted or exposed reinforcement, steel, or
structural steel in the deck joint substrate.
5. Evidence of water leakage on the underside of the deck.
6. Evidence of noise during the passage of vehicles over the joints.
7. Restriction on freedom of joint movement.
8. Evidence of rotation, tilting, or settlement.
9. Incorrect joint opening or improper joint clearance and alignment.
Each of the aforementioned defects is an indicator of the degree of deterioration of the
expansion joint system. The observed deterioration phenomena play a major role in
establishing the deterioration curve of the expansion joint system under study, e.g., the
service life of the system.
In recent years resources for the repair or replacement of any type of expansion joint have
become extremely scarce. As a result, the cost-effectiveness of the various expansion
joint systems on the market becomes the most important aspect in deciding which type to
use. This decision, unfortunately, is not an easy one to make. The difficulty arises from
the fact that the service life of any system is affected to a noticeable degree by the level
of service on the bridge, the environmental conditions in the area, and several other
secondary parameters. The possible change in any of those parameters can affect the
expected lifetime of the expansion joint system to varying degrees. This necessitates the
generalization of the service life concept to allow for all possible parameters.
15
CHAPTER 3
METHODOLOGY
The research can be divided into seven tasks shown as follows:
1. Literature Search
The purpose of the literature review was to find any information from older studies on the
topic of expansion joints. This procedure also helped in structuring the research. Once a
beginning process is determined for a research project, knowledge and qualitative
information can be conjoined to produce effective results in the research. Subsequently,
search on the topic of expansion joint systems in published books and technical journals
was performed, and special emphasis was given to the various classifications of
expansion joint systems, contemporary practices, and future trends.
2. Background Review
A broad review of in-service expansion joint systems currently used by INDOT was
conducted, and those systems already recognized as potential candidates for immediate
use by INDOT New Product Evaluation Committee were also evaluated. This step also
included an investigation of the major problems encountered, any possible pitfalls
causing early failures, the expected improvements in the selected systems, and the
parameters attributing to successful performance.
3. Investigation of Surrounding States
Direct inquires were made into the current practices of the surrounding states. Special
emphasis was given to identifying the expansion joint systems that have successful in-
service performance record and their strengths and weaknesses.
16
4. Establishment of Evaluation Criteria
Based on the literature search and information found in the current practices of INDOT
and surrounding states, an evaluation criteria and procedure for in-service systems was
developed. General appearance, condition of anchorage, debris accumulation, water
tightness, surface damage, noise under traffic, ease of or need for maintenance, and/or
other factors were established as the criteria.
5. Expert Interview
Various specialists in the area of bridge deck expansion joint systems were interviewed to
verify the materials collected in the previous steps. The interviews with the experts form
the field, design groups, research labs, and market suppliers helped to develop a more
reliable evaluation mechanism and identify countable expansion joint systems that can
accommodate for 4 inch movements and that have at least 10 years service life.
6. Field Assessment
Once the evaluation mechanism was developed and verified by experts, field assessment
on the identified expansion joint systems was performed. The objective was to
experiment and to assure the reliability of the evaluation mechanism and to establish
whether the evaluated expansion joint systems actually performed in the field as designed
before the guideline policy was drafted for general implementation by INDOT.
7. Policy Development
The results from the above steps were synthesized to formulate standard provisions for
using bridge deck expansion joint systems in Indiana. A draft policy was introduced to
all the concerned parties for further input, and the feedback was incorporated into a final
policy statement with recommended implementation procedures.
17
A flow chart depicting the methodology of this research is shown in Figure 3.1 below.
Figure 3.1 Research Methodology
Literature Review
In-State Site Visit In-State Interviews
Draft Questionnaire
In-State Pilot Study
Surrouding StatesInterviews
Establish EvaluationCriteria/Schemes
Massive QuestionnaireSurvery Field Assessment
Policy Development &Recommendations
Final Repport
18
CHAPTER 4
LITERATURE REVIEW
Expansion joints are widely used across the United States, which has led to some studies
on the performance and rating of joints. These studies were a solid base for conducting
this research and the information provided from the literature gave some insight on the
performance and life span of the INDOT joints. The literature review was limited to
certain joints, however, and often times did not include newer designs. Therefore, it was
very important to use the literature as a framework only for conducting research and
relaying pertinent information found.
One report of note (Fincher, 1980) was an INDOT project that evaluated the progress of
rubber expansion joints for bridges, which included the Transflex 150-A, Transflex 200-
A, Transflex 250-A, Transflex 400-A, Transflex 650, Wabo Flex SR-1.5, SR-2.5, SR-4.0,
SR-6.5, Delastiflex CP-200, Reynolds Aluminum, Fel-Pro Type T-30, and the Wabo
Maurer Strip Seal SB-200, SB-300, S-400E. The Wabo Maurer Strip Seal is no longer
used by INDOT. However, strip seal systems are still commonly used.
The second report (FHWA, 1983) was performed on many types of joints. The joints
included were the Compression, Strip Seal, Sheet Seal, Tooth Finger, Modular, and
Sliding Plate, and the performance of these joints, as well as the evaluation criteria
process, was documented. INDOT currently uses all of these joints in existing bridges.
The newer acceptable joints are the compression, strip seal, and modular types.
In the early 1960’s and 1970’s, the Watertight Bridge Deck Expansion Joint was
developed and put in use. Up until the late 1970’s, FHWA conducted a National
Experimental and Evaluation Program called the program NEEP II, in which 40 states
participated and 825 joints were investigated across the nation. INDOT also participated
in NEEP II and 97 joints from Indiana’s 38 structures were evaluated.
19
In 1983, FHWA launched another research program entitled “Experimental Project No. 5,
Bridge Deck Expansion Joints.” Field review and evaluation was performed on 1,119
expansion joints with five or more years of service. Arkansas, Maine, Michigan,
Nebraska, Ohio, and Pennsylvania participated in this research program, which was
completed in 1987.
Between May 1990 and September 1991, FHWA conducted a follow-up field evaluation
on modular and finger expansion joints. There were 136 and 42 respectively for each.
Twelve state Departments of Transportation (DOT) participated in this effort. The
findings from the above three studies can be summarized as follows:
I. INDOT Findings by Howard Fincher in 1983
Fifty percent of the assessed joints had poor vertical alignment, and 40% had
snowplow damage. There were many premature sealant failures and none of the
joints evaluated had substantial merits due to the following facts. Sixty percent of
them were leaking water and 40% of them were experiencing problems
detrimental to the service life of the joint.
II. FHWA-NEEP II Findings by George Romack in 1990
A. Metal Reinforced Elastomeric Seal system was rated as poor.
B. Compression Seal expansion joint system was rated as fair.
C. Strip Seal expansion joint system was rated as fair.
D. The sample size of Modular, Finger Dam, and Sliding Plated expansion joints
evaluated in the study were too few to conclude.
E. Other findings
1. The condition of the bridge structure located below the deck was directly
dependent upon the watertightness of the expansion joint.
2. Skewed joints are more susceptible to buckling and/or folding or neoprene
damage.
20
3. The successful performance of the joint device is greatly affected by the
quality of the anchorage system used.
4. The average rating of the B.S joint was slightly higher than the S.S. joint
F. Other Concerns/Issues
1. Lack of designer’s awareness of the critical importance of the bridge joint.
2. Plan details need to clearly show the joint installation procedure.
3. Inspection should be by well-trained inspectors.
4. The use of specialty constructors should be considered.
5. Consideration should be given to making manufacturer responsible for this
installation.
6. A maintenance program is a necessity.
III. Findings from Study on Modular and Finger Expansion Joints by George Romack
in 1992.
A. Modulars were performing as intended.
B. Fingers were performing as designed, although half of them had minor scrapes
and gouges.
C. Other concerns/issues
1. Whether the particular system will provide for the necessary bridge
movements and properly control the bridge runoff.
2. Quality of the fabrication of the components.
3. Adherence to plan details to insure proper installation.
4. Accessibility of proper inspection and maintenance activities.
5. Product warranties from the manufacturer.
6. Incomplete AASHTO specification.
7. Limited research and testing by the joint industry.
8. Insufficient slope for troughs to activate self-cleaning.
21
IV. Findings from Studies on B.S. and S.S. Expansion Joints by Different State
DOTs.
A. The study conducted in Maine (Price and Simonsen 1986) showed that the S.S.
joint was performing well and that the B.S. joint performed well if a good
adhesive was used and it was properly installed.
B. The studies conducted in Arkansas (Benson 1986) and Pennsylvania (Dahir and
Mellot 1985) showed that the B.S. and S.S. joints were approximately equal in
overall performance.
C. The study conducted in Ohio (Minkarah et. al. 1987) showed that the performance
of the S.S. joint was slightly better overall than the B.S. joint.
Based on the literature review, questionnaires were designed and surveys were conducted
of bridge inspectors and engineers to obtain more insight on the performance of
expansion joints. The surveys’ implementation and their results are described in the next
chapter.
22
CHAPTER 5
QUESTIONNAIRE SURVEY
Questionnaires were developed to help to evaluate the joints investigated in this research.
The questionnaire survey played an important role in this study because by soliciting the
opinions of bridge inspectors and engineers, a better understanding can be obtained on
joint problems and their causes, advantages, possible improvements, and service life.
5.1 Introduction
Two surveys and a follow-up survey were conducted. The first survey and the follow-up
survey were designed for Indiana bridge inspectors and the second survey was designed
for bridge inspectors in Indiana and the surrounding states, i.e., Michigan, Ohio, Illinois,
and Kentucky. The follow-up survey will be introduced in detail in section 5.5. The first
survey questionnaire is in Appendix A and the second survey is in Appendix C of this
report.
Five types of joint are included in the survey, B.S., S.S., I.A. (poured sealer and neoprene
seal), XJS, and Polymer Modified Asphalt joints (LDI and PaveTech). The
questionnaires are divided into three parts:
1. Background
This part of the survey established the years of experience of the person completing
the questionnaire, his/her title of position, and district in which he/she is working.
The years of personal experience were later used as the weights in calculating the
ranking of the answers.
2. The Problems, Causes, Merits, and Improvements Associated with the Bridge Deck
Expansion Joints
23
This part asked the respondent to identify, for each type of expansion joint, what
he/she thinks are the most serious problems and their causes, advantages, and possible
improvements. Respondents were asked to select three answers for each question by
the order of the severity (for problems and causes), the importance (for advantages),
or the possibility (for improvements).
3. Recommendation
In this part the respondents were asked to estimate the life of each type of joint; to
select three better joints in their opinions; and to provide their personal comments on
the bridge expansion joints as well as the questionnaire design.
Sample answers were attached with the questionnaires; however, if none were found
suitable from the list of sample answers, the respondent could write his/her own answers.
The two questionnaires were slightly different because the questions of the second survey
were modified for more detail based on the answers of the first survey. The format of the
second survey was also changed to facilitate filling out the questionnaire. Also in the
second survey, two more types of joints were added (I.A. joints were separated into those
with poured sealers and those with neoprene seals, and the PaveTech joint was added).
Respondents were also asked to select three better joints as well in the second survey.
5.2 Analysis of the First and Second Questionnaire Survey Data
1. Joint problems
In this part, respondents were asked to provide the three most severe problems for
each joint by using the numbers 1, 2, and 3, with one representing the most severe.
Each problem was subsequently ranked by the score, which was calculated by the
weighted average method (using years of experience as the weight) for each type of
the joint. Finally, the total score of each problem was divided by the number of
people who selected it. The problem with the lowest minimum value is indicated as
24
the most severe problem, the second minimum value as the second most severe
problem, and the third minimum value as the third most severe problem.
2. Causes of joint problems
After identifying the most severe problems of each joint, their causes were identified
from the answers of correspondents who selected those problems as the most severe
ones in the first part. Then the method similar to the ranking process of the most
severe problems was used to obtain the three most likely causes for each problem.
3. Strengths and improvements of joints
The same method as ranking problems was used.
4. Estimated life of joint
The estimated service life of each type of joint by each respondent was recorded from
the questionnaires. Then the weighted average (using years of experience as the
weight) method was used to calculate the estimated life of each joint.
5. Recommended better joint
Two methods were used here. The first one was the weighted average method as
used above, and the second one was to sum up the values assigned to each joint and
divide it by the number of people who selected it.
6. Comments
Many comments were made on the questionnaires, which are summarized and
discussed in more detail later in this chapter.
A numerical example demonstrating the analysis of survey data is shown in Appendix E.
25
5.3 Implementation of the First and Second Questionnaire Survey
In the first survey, five types of joints were investigated: Compression Seal Joints (B.S.),
Strip Seal Joints (S.S.), Jointless Joints (I.A.), Poured Dow Corning Silicone Joints
(XJS), and Polymer Modified Asphalt Joints (LDI). This survey was distributed to
bridge inspectors and engineers in Indiana only at an annual inspector meeting. Eighteen
responses were finally received and covered all six districts and the Central Office of
INDOT.
In the second survey, seven types of joints were included. In addition to the original ones
in the first survey, the Jointless joints and the Polymer Modified Asphalt joints were each
separated into two subtypes. They became the Jointless joint (I.A.) with Neoprene Seal,
the Jointless joint (I.A.) with Poured Sealer, Polymer Modified Asphalt joints (LDI), and
Polymer Modified Asphalt joints (PaveTech). This survey was conducted in Indiana and
four surrounding states: Michigan, Ohio, Kentucky, and Illinois. In Indiana, the
questionnaires were sent out to the same people who filled out the first survey. In
addition to gathering information that was lacking from the first survey, the second
survey could also be used to confirm the results of the first survey. As for the
surrounding states, the questionnaires were sent out to the bridge engineers and bridge
inspectors in each district. Table 5.1 shows the number of questionnaires issued and
returned in each state. The number of surveys returned is much less than the issued
number partly because some districts returned one copy of the questionnaire to represent
the common opinions in one district instead of returning each inspector’s survey.
Table 5.1 Number of Questionnaires Issued and Returned
Issued Returned Effective Illinois 27 9 9 Indiana 20 8 7 Kentucky 34 7 7 Michigan 9 1 1 Ohio 36 8 8 Total 126 33 32
26
5.4 Discussion of Findings from the First and Second Questionnaire Survey
The results of the first and second questionnaire survey are shown in Appendices B and
D. Following is the analysis and summary of those results. Findings on Each Type of the Joint The findings described here are from the questionnaire survey results, i.e., the most
severe problems and their causes, possible improvements, advantages of each type of
joint, and comments from respondents. The quantitative results of two surveys are shown
in Appendices B and D; following is a summary of the important findings.
1. B.S. Joint
Spalled concrete and loose seal were selected and designated as the most severe problems
for this type of joint. Loss of concrete for B.S. joint leads to loose joints and leaks with
subsequent salt deterioration and spalling of back wall, substructure bridge seats, and
bearing areas. This in turn can cause raised decks and have an impact on traffic. Debris
problems also occur in some cases and the seal can become hardened, whereby no
expansion back to the original thickness occurs after a period of time.
The aforementioned problems were possibly due to the impact of traffic loadings,
incorrect joint openings, and failure of bonding agents. The traffic loadings caused the
concrete to spall and crack and brought debris on the seal. The incorrect joint openings
and failure of bonding agents could accelerate the deterioration of bearings.
There are several suggestions for solving problems stated above. 1) Adding admixtures
to concrete to increase its resistance for freezing and thawing and reduce cracks. 2) The
seal should be tested before installation. 3) Armoring the joint against the live-load
impact from traffic. 4) Strengthening the bonding between seals and the concrete.
27
In summary, this type of joint could function well if concrete and seals are in good shape.
Some respondents felt it is easy to replace this type of joint and maintain but some did
not.
2. S.S. Joint
Debris seems to be the major problem of this type of joint. Deicing abrasive sand and
blowing sand usually accumulate in the S.S. joint and passing trucks pound down sand to
pop out the rubber from holding glands. Sometimes armor angle breaks under wheel
loading can catch snowplows and create maintenance problems.
Debris, poor installation and maintenance seemed to be major causes of problems of the
S.S. joint. Poor or faulty drainage details, deicing chemicals, snowplows, and traffic
loadings all contributed to the problems of this type of joint and shortened its service life.
Several suggestions to the above problems were proposed. 1) The joint should be
designed with self-flushing capabilities, such as the sufficient slope or larger curb
opening. 2) It is better to use non-corroding extrusion and larger diameter bolts to hold
down the anchor blocks. 3) Regular and frequent maintenance should be conducted.
Some respondents indicated that this type of joint is very durable if well maintained. It
may be more expensive than the B.S. joint but considering maintenance it is more cost
effective than B.S. joint.
3. I.A. Joint (Poured Sealer)
It appears from the survey that there are no major complaints with this type of joint.
However, it was found that joint materials do not always completely fill the opening and
spalled and cracked concrete occurred 5 to 10 feet from the end of the deck.
28
The causes of problems include poor installation, improper selection of materials, traffic
loadings, and deicing chemicals. The snowplows also occasionally caused seals to break.
Several suggestions were made on the survey for improving the performance of this type
of joint. 1) The notch should be made deeper and filled with silicone. 2) Beveled edges
can reduce concrete spalling due to wheel loads. 3) Approach slabs should be tied to
deck to eliminate movements.
The advantage of this type of the joint is that the poured silicone can flow into and
conform to any concrete imperfection due to construction forming of concrete seal edges.
Some respondents commented that it is durable and maintenance-free.
4. I.A. Joint (Neoprene Seal)
The problems and suggested improvements for this type of joint are similar to the one
stated above. However, most respondents indicated that its performance seems to be
worse than the I.A. joint with the poured sealer.
5. XJS Joint
This type of joint has several problems. The epoxy materials were found to come in
contact with traffic, which caused holes in the seals. This could be due to installing it too
high, structure expansions causing it to shove upwards, or hot weather. There are debris
and gravel problems for this type of joints, and the nosing materials are also frequently
damaged, which may cause leaking problems. The silicone material also was found to be
not mixed correctly and frequently there were holes and cracks on the seal.
The problems of this type of joint could be caused by poor installation and inferior
quality of bonding agents. Poor installation caused the silicone to be installed too low or
too high and frequent damages of bonding agents could cause the holes and cracks on the
seal.
29
Several suggestions were made for problems of this type of joint. 1) The polymers
should be kept slightly below the top of the deck elevation and the chamfer should be
large enough to prevent spalling of the nose. 2) Silicone thickness should be placed
correctly and the silicone material should be mixed correctly. 3) Detailed installation
plans should be provided by the manufacturer or the contractor.
Some respondents preferred this type of joint because of its easy installation and repair;
this type of joint can be repaired by bridge crews within one working day. It is also easy
to make a spot repair in one particular location without removing the entire joint.
6. LDI Joint
Several problems were found with this type of joint. The polymer modified asphalt
materials are found missing with steel plates rusted and cracked. The asphalt materials
also experienced shoving and rutting during hot weather and had cracks in the shoulder
area. The mixing of the materials was not up to the standard quality.
The problems stated above could be caused by the unacceptable range of the bridge
movement or the inferior quality of asphalt materials. The large bridge movement could
cause the cracks on the seal and the inferior quality of asphalt materials may cause
serious shoving and rutting during hot weather.
There were some suggestions for improving the performance of this type of joint. 1) The
bonding between the header and the adjacent concrete should be improved by using
better materials. 2) The material testing should be done before installation. 3) Selection
for use in locations where heavy truck traffic is not present or bridge movement is small
may improve the joint performance.
This type of joint has the advantages of providing excellent ridibility, would not require
flushing, and would not be damaged by snowplow blades.
30
7. PaveTech Joint
The problems and improvements of this type of joint are similar to those of LDI joints.
However, its polymer modified asphalt material was found to be softer than that of LDI
and hence the problems of shoving and rutting were more serious.
Overview of the Joint Problems
The overall ranking of the joint problems was obtained by using the result of the first
questionnaire survey (In-State). Problems of each type of joint were first ranked
according to the weighted average score considering the years of experiences of each
respondent. After the ranking of problems for each type of joint was obtained, the
ranking of each problem under each type of joint was summed and the final scores were
used for the overall ranking. For instance, assume that there are five joint problems and
five types of joints shown in the Table 5.2 below. Five joint problems were first ranked
under each type of joint. By summing the ranking of each problem under each type of
joint, the total scores were put in the column entitled “Total”. The total scores were then
used to obtain the overall ranking of the joint problems. The numerical example of the
data analysis was shown in Appendix E and the actual result was shown in Table 5.3.
Table 5.2 Methodology for Ranking Overall Joint Problems
Joint Problem B.S. S.S. I.A. XJS PMJ Total Ranking
Damaged seal 1 3 3 1 1 9 1
Deteriorated bearing 2 4 5 3 2 16 3
Damaged adhesives 3 1 1 4 4 13 2
Water leakage 4 5 2 2 5 18 4
Spalled concrete 5 2 4 5 3 19 5
31
Table 5.3 Overall Ranking of Joint Problems (First Survey)
Problem Ranking Symptom
a 1 Loose, torn, split, cracked, damaged, hardened seals, or holes in seals
j 2 Deterioration along bearing areas on the pier caps and on the columns
b 3 Damage of epoxy fillers or adhesive lubricants causing separation of the joint material from the joint face
e 4 Evidence of water leakage on the underside of the deck or at the curbline
d 5 Cracked and spalled concrete, and rusted or exposed reinforcement steel or structural steel in the deck joints substrate
k 6 Poor ridebility
c 7 Accumulation of debris and incompressible materials in the seals
f 8 Evidence of noise during the passage of vehicles over the joint
h 9 Evidence of rotation, tilting, or settlement of joints
i 10 Incorrect joint opening and alignment
l 11 Inadequate skid resistance
g 12 Restriction on freedom of joint movement causing problems such as transverse movements of the deck
n 13 Loose, torn, split, cracked, damaged, or hardened nosing materials
q 14 Traffic comes into contact with silicone
p 15 Tracking and flowing of polymer during hot weather
32
Table 5.3 showed that the five most serious joint problems obtained from the surveys are:
broken seals, deteriorated bearings, damaged adhesives, water leakage, and spalled
concrete and rusted steel. The seal problems include loose, torn, split, cracked, hardened,
or holes in seals. Deterioration of bearing happens on the pier caps and the columns.
Damage of adhesives or epoxy fillers causes separation of the joint material from the
joint face. Water leakage happens on the underside of the deck or at the curbline.
Concrete are usually found cracked and spalled and steel found rusted or exposed in the
deck joints substrate.
Debris accumulation, traffic loading, poor installation, and inferior material quality
frequently cause the damage of the seals. Bearing is deteriorated by deicing chemicals,
rain, leaking joint, or poor maintenance. Poor installation and inadequate bonding
strength may damage the adhesives. Water leaks from the damaged seal and adhesives,
and spalled concrete. The traffic loading, deicing chemicals, and the poor quality of the
used material make the concrete and steel problems worse.
Several suggestions were made to solve the aforementioned problems. The joint
materials such as seals or adhesives should be tested and well installed by the specialty
contractor. The joint can be armored to be protected against the traffic impact. Concrete
needs to be protected by sealers and the plate and bars holding the seal need to be more
corrosion-resistant. A large curb opening can flush the joint itself clear and reduce the
accumulation of debris. Regular and frequent maintenance is important to extend the
service life of the joint. Finally, the joints need to be selected from those, which can meet
the requirement of the deck expansion range and the traffic density.
Some of the problems may happen more frequently to one type of joint than the other.
For instance, cracked and spalled concrete happened most to the B.S. joint while the
damage of the adhesive lubricants usually happen to the XJS joint. The rest of the
problems that were ranked from the 6th to 15th can also be seen from the table. The
results of the overall ranking of the joint problems for the second survey and the follow-
up survey (introduced in Section 5.5) were provided in Appendix F.
33
Estimated Life of Joints
The results of both surveys regarding the estimated life of the joints were very similar, as
seen from Table 5.4 and 5.5. The S.S. joint was rated to have the longest estimated life in
both surveys, followed by the B.S. joint, and then the I.A. joint. The major difference
among them was in the LDI joint. In the first survey, the LDI joint had the shortest
estimated life, 3.5 years. In the second survey, the estimated life of the LDI joint is 5.74
years. Thus, the LDI joint was ranked before the XJS joint in the second survey while it
was last in the first survey. In summary, it can be concluded that the S.S. joint has the
longest estimated life on average in both surveys. The I.A. joint with a poured sealer has
a longer life than the one with a neoprene seal. The performance of the PaveTech joint
was very similar to the LDI joint. The XJS, LDI, and PaveTech joints had a considerably
shorter estimated life compared to the S.S., B.S., and I.A. joints.
Table 5.4 Estimated Joint Life (Survey #1)
Joint Type S.S. B.S. I.A. XJS LDI
Weighted
Average (yr.) 11.9 11.706 8.728 5.19 3.502
Range (yr.) 0 – 20 0 - 20 0 – 20 1 - 15 1 - 10
S.D. (yr.) 5.79 5.59 5.91 3.97 2.85
Table 5.5 Estimated Joint Life (Survey #2)
Joint Type S.S. B.S. I.A.
(Poured sealer)
I.A.
(Neoprene seal) PaveTech LDI XJS
Weighted
Average (yr.) 10.92 10.3 9.79 7.33 5.82 5.74 5.56
Range (yr.) 1.5 –
25 2 - 20 1.5 - 20 1.5 – 15 1.5 – 10 0 - 20 0 - 20
S.D. (yr.) 5.34 4.86 6.24 4.07 2.74 6.9 6.41
S.D.: Standard Deviation
34
Recommended Types of Joints
Since this question was only asked in the second survey, there is only one result
available, which is shown in Table 5.6. Two ranking methods were used and they
showed very different results. The S.S. joint was one of the top two recommended joints
using both methods. The I.A. joint with a poured sealer is preferred more than the one
with a neoprene seal, and the PaveTech joint is the least favored joints in both methods.
Table 5.6 Recommended Types of Joints
a. By the weighted average score
Ranking 1 2 3 4 5 6 7
Joint type B.S. S.S. XJS I.A.
(Poured
sealer)
I.A.
(Neoprene
seal)
PaveTech LDI
b. By the average score (not considering the years of experience)
Ranking 1 2 3 3 5 6 7
Joint type S.S. I.A.
(Poured
Sealer)
LDI I.A.
(Neoprene
seal)
B.S. XJS PaveTech
5.5 Follow-up Survey
To better understand the performance of each type of joint in each specific category,
namely, riding quality, water leakage, noise, and difficulty of maintenance, a follow-up
survey was conducted. Bridge inspectors were asked this time to rank the joint problems
according to the aforementioned four categories. Six inspectors from each district of
INDOT and one inspector from INDOT’s Central Office participated.
35
Seventeen problems were selected from the first questionnaire for ranking in the follow-
up survey. The problems were ranked one through seventeen by survey participants
according to their severity in each category, with one being most severe and seventeen
the least severe. For instance, in the categories of riding quality, water leakage, and
noise, inspectors were asked to rank each problem according to its contribution to the
poor riding quality of joints, water leakage, and noise. In the category of difficulty of
maintenance, problems were ranked depending on how severely each problem influenced
the difficulty of repair.
All of the inspector’s rankings in each category were then summarized to obtain the final
ranking in each category. The ranking of each problem was then matched and assigned
to the three selected most severe problems from the result of the first survey and a total
score was obtained for each type of joint in each category. Since smaller numbers in the
ranking designated more severe problems in a particular category, a larger total score
indicates better performance by a joint in that category. The results are shown in Table
5.7.
Table 5.7 Performance of Joints based on Riding Quality, Water Leakage, Noise,
and Difficult of Maintenance
Ranking Riding Quality Water Leakage Noise Maintenance
XJS S.S. XJS XJS & S.S.
S.S. LDI S.S. B.S.
I.A. B.S. B.S. LDI
B.S. & LDI XJS I.A. I.A.
Good
Worse I.A. LDI
The results of the follow-up survey generally confirmed the results of the first and second
questionnaire surveys. The S.S. joint performed better than the B.S. joint, which then
performed better than the I.A. joint. The LDI did not perform well in any category,
except water leakage.
36
The major difference in the follow-up survey results was that the XJS joint performed
better than other types of joints in almost every category except water leakage. However,
possibly due to its short history of usage and long-term performance was not well known,
in the first and second surveys, its ranking as to its estimated life and recommended type
of joint was not good. Furthermore, this type of joint is usually installed where the
expansion range is small and the traffic volume is low. It could become a good joint if it
proves to have good long-term performance and meet various expansion and traffic
requirements. The questionnaire of the follow-up survey, the analysis of data, and the
result were shown in Appendix F.
5.6 Summary
1. Almost all the severe problems of each type of joint are related to the seal and the
concrete, and these problems usually consist of holes in the seal, hardened seal,
cracked seal, loose seal, and torn seal. The problems of concrete are mainly spalled
concrete and cracked concrete. The seal and concrete problems often cause leaking
of the joint, which can cause the deterioration of the substrate elements such as
abutment walls, caps, bearings, and beam end.
2. The causes of most joint problems are related to traffic loading, snowplow damage,
weather, poor installation, inferior materials, and the incorrect selection of the joint
type.
3. One major problem of the B.S. joint is spalled and cracked concrete. The prudent
preparation of concrete will insure its quality. Further, the seal materials should be
tested before installation.
4. One major problem of the S.S. joint is the accumulation of debris and grit. How fast
the debris accumulates or how well the maintenance is done could affect the outcome.
One suggestion for solving this problem was to make a larger curb opening or a
sufficient slope so that rain can flush the debris.
37
5. The causes of several XJS joint problems were poor installation, poor workmanship,
and inadequate site preparation. It can be concluded from the survey that the
performance of the XJS joint depends greatly on the installation quality, i.e., the
mixing of materials and the thickness of the silicone.
6. The LDI and PaveTech joints both have similar problems and causes. Their seals can
be pushed up during hot weather (rutting) and then holes are formed in the seal. The
inferior materials used in both types of joints and installation of this particular joint at
locations with high traffic volume, as well as its greater expansion requirements, are
also main concerns in its poor performance.
7. The results for estimated joint life in the first and second survey were very close. The
S.S., B.S., and I.A. joint were ranked first, second, and third in both surveys
according to the length of their estimated life. The I.A. joint with poured sealers lasts
longer than the one with neoprene seals. The performance of the PaveTech joint was
very similar to the LDI joint. The XJS, LDI, and PaveTech joints were rated to have
considerably shorter estimated lives compared to S.S., B.S., and I.A. joints.
8. The overall ranking of the joint problems showed that the five most severe problems
were the seal problem, deterioration along bearing areas, damage of adhesive
lubricants, water leakage, and cracked and spalled concrete. However, some of the
problems may happen more frequently to one type of joint than the other. For
instance, cracked and spalled concrete happen most to the B.S. joint while the damage
of the adhesive lubricants usually happens to the XJS joint.
9. The recommended joints, using both ranking methods, were very different. The only
conclusions that can be derived is that the S.S. joint remained among the strongly
recommended joints and the PaveTech joint is among the weakest joints in both
rankings.
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10. The results of the follow-up survey generally confirm the results of the previous two
questionnaire surveys. The performance of each type of joint, from good to worst,
was shown in the pattern of the S.S., B.S., and I.A. joints in the categories of riding
quality, water leakage, noise, and difficulty of maintenance. The LDI joint did not
perform well in any category except water leakage. Although the XJS joint was
ranked well in most categories, its long-term performance needs to be evaluated
because of its short history of usage.
39
CHPATER 6
IN - STATE SITE VISITS
Several types of joints were observed and their performance evaluated by site visits to see
the problems currently identified with INDOT bridges (no county or city maintained
bridges have been included in the scope of this project). Of the bridges visited, the joints
observed were the Compression Seal, the Strip Seal, Modular, Polymer Modified
Asphalt, Integral Abutment, Poured Silicone, Tooth/Finger, and Modular. All of the
joints were photographed and documented, and their performance evaluated by visual
inspection of their deterioration.
The installation of joints was also observed during the site visits, namely the placements
of a strip seal joint and a poured silicone joint. The strip seal joint was installed on I-70
and the poured silicone joint was installed on a state bridge. These joints and other joints
stated previously were observed twice, one in the summer and the other in the winter, to
establish a seasonal difference in the joint condition. However, there was no noticeable
difference between winter and summer for these joints. The reason might be that the
joint was observed for only one winter. There was small difference in the joint’s
appearance, but it could have been caused by other factors such as age, traffic,
installation quality, which were imposed on the joints with the weather factor at the same
time.
The following paragraphs describe the observations made in the site visits. Please see
Appendix G for photographs of these joints.
- B.S. Joint
The B.S. joint was located on I-465 over Fall Creek Road. The seal looked fine, but
the surrounding concrete was spalled and had cracks. This observation agrees with
the results of the survey.
40
- Flexcon 2000
This is a type of joint similar to the XJS joint. The major difference is in the joint
materials used. Two locations were visited, one on I-65 and Greenwood Road and
the other on I-70 adjacent to Harding Street and Conrail. Both joints still contained
the heading materials, but the seals were severely broken. The first one was loose
and had many holes; and the second one was split and cracked. The seal of the
second joint was not deep enough and came in contact with vehicle tires, which could
be the reason for its seal’s rapid deterioration. The heading material in the second
joint was also severely worn.
- I.A.
This I.A. joint is located on South Port Road over Little Buck Creek. This joint and
its surrounding concrete looked very good and there were no signs of deterioration.
- LDI
This LDI joint looked good in its appearance. However, there were some small
cracks on the edge of the joint, which could be due to the debonding of the joint
materials and concrete.
- Modular
This joint is located on I-65 over White River. This joint appeared to be performing
well but debris was already accumulating in the seal and there was spalled concrete
on the edge of the joint.
41
- PaveTech
Two PaveTech joints were observed. The first one was located on I-65 over Martin
Luther King Drive and the second one is located on I-65 at Clinton Street. The first
joint contained holes and parts of the surface were worn out. The baker rod fell off
the joint as can be seen from the pictures.
The second joint also had serious problems with deep holes in the seal. These holes
could be attributed to the fact that the polymer materials of the PaveTech joint are
soft during the hot weather. Thus, holes are formed under the heavy traffic load.
- Sliding Plate
This joint was located on I-70 eastbound over Rural Street. The overall appearance
of this joint was fine but there was a hole in the plate, which could be due to the
pounding of the traffic.
- Tooth Finger
This joint was located on I-70 eastbound over Rural Street. The overall appearance
of the joint was good except that there were a few broken teeth on the plate.
- S.S.
There were two S.S. joints visited. The first one was located on the 38th Street
eastbound lane over I-65 and the second one was on I-74. The first joint contained
substantial debris in the seal and some portions of the seal were loose (the photo in
Appendix G shows that a hand can go through the seal). The anchors were
deteriorated as seen from the photos.
42
The second joint had been installed for about one year and its performance looked
fine, however, substantial debris had already accumulated in the seal.
- XJS
There were two XJS joints visited. The first one was located on I-74 at the east side
of Indianapolis and the second was located on I-59 near Carbon. The joint’s
appearance looked good but actually it had holes (the photo shows the finger able to
go through the seal), and the seal was debonded from the edge of the heading
materials. From the bottom of the bridge deck it was observed that the bearing was
seriously deteriorated, which indicated that this joint had a serious leaking problem.
The second joint was performing well since it had been installed for only one year
and not much debris had accumulated. This could be also due to the fact that this
joint was located on a state road, which has less traffic. There was no nosing material
and small cracks were seen on the edge of the joint.
In summary, the problems observed in the field paralleled the results of the questionnaire
survey. Although only a few samples were observed for each type of joint, the results of
the questionnaire survey were confirmed by these site visits.
43
CHAPTER 7
EXPERT INTERVIEWS Interviews were performed with INDOT staff members and those of surrounding state
DOTs of Illinois, Kentucky, Michigan, and Ohio. These interviews were conducted by
telephone or person-to-person. The objective of the interviews was to determine each
state’s practices for selecting, evaluating, and maintaining the joints.
7.1 In-State Interviews
Indiana Department of Transportation Informal Expansion Joint Approved List
From the interview with NPEC committee members, it was discovered that INDOT does
not have a formal approved list of expansion joints. The current method of selecting
joints is basically a trial and error process. In the past, joints were selected based on
vendor data without any formal approval. The joints then were put into use and evaluated
on performance. If they performed well, then they became commonly used. Poor
performance of the joint resulted in suspending its use or the manufacturer was asked to
redesign it and complete the testing process once again. Once this process was
completed, then an evaluation was done by INDOT and the joints were either continued
in use or discontinued. This whole process has repeated itself a few times in the past 20
years. Since the formation of the NPEC, the “trial and error” process has been discarded.
Hence, a criteria scheme is needed to assist in the review of joints and joint material
before they are installed.
This following list of expansion joint products was provided by Advanced Performance
Products of Indianapolis, a supplier of joint materials to INDOT. These joints are
currently being supplied to INDOT.
1. B.S.
Watson Bowman
D.S. Brown
44
2. S.S.
Watson Bowman
D.S. Brown
R.J. Watson
Structural Accessories
3. Modular
Watson Bowman
D.S. Brown
4. Poured Silicone
Dow Corning
5. Integral Abutment (I.A.)
The Maintenance of the Bridge Expansion Joints
The maintenance of bridges and roads is fulfilled by INDOT after the contractor has
fulfilled the contract requirements. INDOT has a two-year cycle of inspection of bridges
to determine their structural state. District bridge inspectors conduct the inspection using
a specific form for this purpose. Once the report has been reviewed, any necessary
repairs are then scheduled.
INDOT allocates a specific amount of money each year to be used specifically for
maintenance; however, resource allocation is usually depleted before all of the projected
work is completed, which could lead to loss of maintenance on bridges, and/or lack of
proper maintenance due to poor time management.
The Use of the Integral Abutment Expansion Joint
INDOT has begun using the Integral Abutment (I.A.) Expansion Joint in most bridge
designs. The purpose of the I.A. joint is to place the expansion characteristics of the
45
bridge onto the approach slabs, which helps prevent maintenance problems and failures
of the joint in the future. However, there have been problems with cracking in the
approach slabs, and the design of the approach slab has changed almost yearly for the
past three years. Underneath the slab and behind the abutment, the area has been
backfilled with granular materials, and the material has changed from sand to coarse
aggregates. There has also been the addition of a corrugated pipe that runs transverse of
the slab behind the abutment to remove water from the area. Once water is in the area, it
can cause the slab to crack and fail and also cause settlement. The current design for the
approach slab allows for expansion onto the slab, which is overlaid with asphalt. The
asphalt allows for more expansion and contraction than does the concrete.
7.2 Surrounding States Interviews
States surrounding Indiana were surveyed to find out current practices on expansion
joints. Particular emphasis was placed on the type of joints used, why they are used, and
their strengths, weaknesses, and performance history. Interviews were conducted with
state DOT officials to obtain these answers.
Michigan
Several bridge engineers with the Michigan Department of Transportation (MDOT) were
contacted to gain information about the techniques and products Michigan uses for bridge
expansion joints. Specifically, MDOT officials were asked to provide a list of the joints
they use and the standards and specifications for these joints. A listing of any rehab jobs
in MDOT was also requested and they responded by e-mailing a copy of plans and
specifications for a rehab job that was designed specifically for expansion joints. MDOT
specifications indicated that they are current using S.S., XJS, and Polymer Modified
joints. They also mentioned that the maintenance work in some districts is subcontracted,
rather than using the in-house force.
46
Ohio
Bridge designers with the Ohio Department of Transportation (ODOT) were contacted
about their use of expansion joints, and they referred us to their web page,
www.dot.state.oh.us/se/standard/metric/indexm.htm, which has standard drawings and
specifications of the type of joints used and their manufacturers. They also supplied the
names of the construction engineers of each district and their telephone numbers. Eight
types of joints are specified in ODOT’s standard drawings and specifications, including
B.S., S.S., Semi-Integral, Integral, Steel Sliding Plate, Modular, and Tooth/Finger joints.
They mentioned that in most rehabilitation jobs for recent years, they tend to use more
I.A. joints because they experienced less maintenance problems.
Mr. Hopwood of the Kentucky Transportation Cabinet also provided information
regarding some of the joints current in use by ODOT, much of which pertained to Semi-
Integral and Integral Abutment bridges. This information included detailed sketches of
integral abutments, a small report about integral abutments that was presented at the
Transportation Research Board’s 75th Annual Meeting in Washington D.C. in January of
1996, and an information packet from a workshop on integral abutments. Average daily
traffic information and types of joints were also provided, as well as an interoffice
memorandum that indicated the polymer modified expansion joint performed poorly in
heavy traffic (Inter-Office Communication, ODOT, 1995). A copy of the standard
drawings and specifications for ODOT joints that are currently in use were included in
this information.
Illinois
Bridge engineers in the Illinois Department of Transportation (IDOT) were asked to
provide a list of IDOT approved expansion joints and their manufacturers, a list of the
district construction engineers, post-construction evaluation procedures, and their
procedure for new products approval.
47
IDOT provided the list of joints below and their manufacturers. They also provided a list
of districts and the engineers to contact. Post-construction evaluation techniques were
discussed in an interview, and it was revealed that IDOT has had only one post-
construction evaluation on expansion joints in the past 10 years. This evaluation began
as a testing of the Poured Silicone joint, for the purpose of observing how well the joint
performed while flooded with water. The research then moved into all joints and a report
was constructed. This report is to be given to at a later date, but INDOT confirmed that
the report shows that the Poured Silicone joint performed well. IDOT’s only other
evaluation is done during the FHWA inspection every two years, where when
maintenance is also performed. The IDOT uses five different levels to rate the joint
condition: 5 for new, 4 for good, 3 for fair, 2 for poor, and 1 for replacement required.
Like INDOT, IDOT has a New Products Evaluation Committee; however, the committee
member to whom we were referred has not responded to the survey request. IDOT also
provided information from the Bridge Design Manual regarding expansion joints.
Illinois Department of Transportation Informal Expansion Joint Approval List
1. Strip Seal
Watson and Bowman
D.S. Brown
2. Neoprene Joint
General Tire
3. Reinforced Neoprene Seal
D.S. Brown
Watson and Bowman
4. Compression Seals (B.S.)
Whoever meets accepted standards
48
5. Poured Silicone
Dow Corning
6. Bonded Preformed Joint
Watson and Bowman
7. Modular
Watson and Bowman
R.J. Watson
D.S. Brown
8. Integral Abutment (I.A.)
Kentucky
The Kentucky Transportation Cabinet was somewhat helpful during the interview
process, however with no backing documentation provided. The following was obtained
from direct contacts with bridge engineers in the Division of Bridges of the Kentucky
Transportation Cabinet:
1. Specifications for the different types of joint materials were provided.
2. Modular joints are not used at all in Kentucky, and there is wide use of Integral type,
B.S. and S.S. joints.
3. Information on their evaluation process and inspector list was referred to a head
bridge engineer, who has not returned any information.
7.3 Summary
1. Although most states DOTs were willing to provide us their approved expansion joint
lists and their specifications and drawings, not much information was obtained
regarding their practices for approving the expansion joints.
49
2. From the interviews and materials collected, it was found that different states have
had different experience using the joints. For instance, ODOT has a good
performance history with the Integral Abutment joints, but has a poor history with the
Polymer Modified joints, while IDOT has a good history with the Poured Silicone
joints. There is consensus among all DOTs that the older joints, such as the B.S. and
S.S., are performing well but could be improved. It was also found that the use of
Integral Abutment Expansion Joints is gaining popularity in the investigated states,
and its design and performance are also being examined and improved.
3. It appears that the maintenance strategies for expansion joints are not specific in the
states surveyed. For instance, MDOT provided information for a statewide
rehab/maintenance program that was dependent upon funding – not necessarily upon
the condition of the bridge. This does not mean that damaged bridges were ignored,
rather they may be repaired instead of replaced. Additionally, most bridge engineers
spoken to mentioned that maintenance and repair measures that have been used for
badly damaged joints have been classified as temporary. In other words, they
suggested that repair measures would be more economical in the long run if joints
were replaced entirely to prevent further damage spreading to reinforcements within
the bridge, resulting in even greater maintenance expenses in the future. A common
complaint was that the temporary measures did not sufficiently prevent seepage.
4. Interviewed engineers seemed to decline favoring any specific expansion joint over
others. They claimed that no joint has been designed that has been proven more
economical over the expected life of the bridge in all applications. Expansion joints
are all too often overlooked in bridges, because they are just a small portion of the
bridge. However, their impact can have costly and severe adverse results if their
selection and maintenance are not appropriate on both old and new bridges.
5. Sometimes joints may not be properly selected by design consultants. The
requirements of the joints for certain applications are not identified and therefore lead
to shortened life. Also, standards and specifications are constantly being revised and
50
consultants may not be aware of revisions and continue to design decks with joints
that were acceptable in the past. Once this happened and the project is then let for
bid, the responsibility of replacing the improper joint with the acceptable one is
placed on the field project engineer. This is often overlooked and the improper joint
is then placed on the bridge.
51
CHAPTER 8
ESTABLISH EVALUATION CRITERIA/SCHEMES Inspectors complete bridge evaluations once every two years according to FHWA and
INDOT regulations and policy. Many components of the bridge are inspected, including
the expansion joints. The evaluation of the joints is currently done based on the personal
experience of each inspector and is then given a ranking of poor, fair, or good. New
evaluation criteria are proposed in this report to provide a uniform rating guideline and
establish a more objective evaluation process.
8.1 Current Practices of Evaluating Existing Expansion Joints The current INDOT evaluation of joints is visual and is based on the experience of the
inspector. The condition of the bridge joint is evaluated on a scale of good, fair, and
poor. The joints of the bridge are evaluated separately from the decks that use a 0 to 9
scale. A type of joint is selected and then rated based on inspector’s experience. There is
no clear definition of good, fair, and poor condition for each type of joint. The ambiguity with the current evaluation system is that it allows decisions to be made
upon personal experience, which can result in subjective observations because of the
differing experiences of individuals. For instance, an inspector who has been inspecting
bridges for 15 years may be more critical than a person who has only one or two years
experience. This problem can be alleviated if standard scheme utilized for the evaluation,
which would give each bridge inspector/engineer the same criteria for evaluating
expansion joint performance.
8.2 Proposed Evaluation Schemes The evaluation scheme for in-service expansion joint systems was developed based on
the literature search, questionnaire surveys, and information pertaining to the current
practices of INDOT and surrounding states DOTs. The criteria of general appearance,
condition of anchorage, debris accumulation, water tightness, surface damage, noise
under traffic, ease of or need of maintenance, and/or other were established.
52
Each type of joint will exhibit different problem symptoms. Thus, specific evaluation
criteria are utilized for each type of joint, including B.S., S.S., I.A., Poured Silicone, and
Polymer Modified joints. There are six different levels of the joint conditions: new,
nearly new, good, fair, bad, and poor. Each condition corresponds to a numerical rating
as 10, 9-8, 7-6, 5-4, 3-2, and 1-0. Except 10 as a single number for the rating, inspectors
can use his/her judgement to decide which number to use for other ratings. For instance,
inspectors can choose the rating 8 if the joint condition falls into the interval of nearly
new but it is closer to the condition good of the next level. If the joint condition is closer
to the condition new of the upper level, then the rating 9 can be chosen. By doing this,
the evaluation process is more consistent and objective since the conditions are classified
into more detail while inspectors can use the subjective judgement to choose one
numerical rating out of two within each condition state.
Finally, the bottom of each table is used in case inspectors cannot find the symptoms on
the list, which although it is intended to be comprehensive, some symptoms might not
happen with each type of joint. Thus, inspectors can fill out the symptoms at the bottom
of the table and put a numerical rating for it. These symptoms will be added in the table
for further modifications in the future. The following pages show the tables of evaluation
criteria for each type of joint.
53
Table 8.1 B.S. Joint Evaluation Scheme
Rating Condition Symptom Appearance Anchorage Leakage Noise
0-1 Poor Joint is missing/fallen out completely
Joint anchorage or surrounding concrete is destroyed. Rusted and exposed deck steel
Evidence of total water leakage
Extreme noise during traffic passage
2-3 Bad Joint is partially in place
Joint anchorage is in poor/brittle condition. Limited deck steel exposure
Evidence of water leakage
Noise during traffic passage
4-5 Fair Joint is in place with debris. Broken seal in small areas with embedded debris
Joint anchorage is cracked/ in bad condition with little or no reinforcing steel exposure
Small water leaks Noise during traffic passage
6-7 Good Joint is solidly in place with debris and no breaks in the seal
Joint anchorage is in good condition with limited cracking and no deck steel exposure
No water leaks evident
Slight noise during passage of traffic
8-9 Nearly New Joint appears new with some debris which does not affect performance
Joint anchorage is in good condition with no cracking and no deck steel exposure
No water leaks evident
Quiet during passage of traffic
10 New Joint has excellent appearance with no debris in joint
Joint anchorage is in excellent/new condition
No water leaks evident
Quiet during passage of traffic
Other Symptoms
Overall Rating 1 2 3 4 5 6 7 8 9 10
54
Table 8.2 S.S. Joint Evaluation Scheme
Rating Condition Symptom Appearance Anchorage Leakage Noise
0-1 Poor Joint is missing/fallen out completely
Joint anchorage or surrounding concrete is destroyed. Rusted and exposed deck steel
Evidence of total water leakage due to holes, loose, torn, split, or hardened seal
Extreme noise during traffic passage
2-3 Bad Joint is partially in place with large amounts of debris
Joint anchorage is in poor/brittle condition. Limited deck steel exposure
Evidence of water leakage due to holes, loose, torn, split or hardened seal
Noise during traffic passage
4-5 Fair Joint is in place with debris. Broken seal in small areas with embedded debris
Joint anchorage is cracked/ in bad condition with little or no reinforcing steel exposure
Small water leaks due to holes, loose, torn, split or hardened seal
Noise during traffic passage
6-7 Good Joint is solidly in place with debris slightly affecting performance
Joint anchorage is in good condition with limited cracking and no deck steel exposure
No water leaks evident, but loose or hardened seal condition
Slight noise during passage of traffic
8-9 Nearly New Joint appears new with some debris which does not affect performance
Joint anchorage is in good condition with no cracking and no deck steel exposure
No water leaks evident
Quiet during passage of traffic
10 New Joint has excellent appearance with no debris
Joint anchorage is in excellent/new condition
No water leaks evident
Quiet during passage of traffic
Other Symptoms
Overall Rating 1 2 3 4 5 6 7 8 9 10
55
Table 8.3 I.A. Joint Evaluation Scheme
Rating Condition Symptom Appearance Cracks on Deck Leakage Noise
0-1 Poor Cracked and spalled concrete, exposed deck and abutment reinforcing steel
Numerous amounts of large midspan cracks on deck
Evidence of total water leakage due to holes, loose, torn, split, or hardened seal
Extreme noise during traffic passage
2-3 Bad Joint is fully intact with large amounts of cracked and broken concrete
Few large midspan cracks on deck
Evidence of total water leakage due to holes, loose, torn, split, or hardened seal
Noise during traffic passage
4-5 Fair Joint is fully intact with small amounts of cracked and broken concrete
Few small midspan cracks on deck
Small water leaks due to holes, loose, torn, split, or hardened seal
Noise during traffic passage
6-7 Good Little cracking and broken concrete around abutments and deck
Little to no midspan cracks on deck
No water leaks evident, but loose or hardened seal condition
Slight noise during passage of traffic
8-9 Nearly New No cracking between abutments and deck
No cracking on midspan of deck
No water leaks evident
Quiet during passage of traffic
10 New New concrete between abutment and deck
No cracking on midspan of deck
No water leaks evident
Quiet during passage of traffic
Other Symptoms
Overall Rating 1 2 3 4 5 6 7 8 9 10
56
Table 8.4 XJS Joint Evaluation Scheme
Rating Condition Symptom Appearance Nosing/Concrete/Steel Leakage Noise
0-1 Poor Joint is missing/fallen out completely
Joint nosing or surrounding concrete is destroyed. Rusted and exposed deck steel
Evidence of total water leakage
Extreme noise during traffic passage
2-3 Bad Joint is partially in place
Joint nosing is in poor/brittle condition. Limited deck steel exposure
Evidence of water leakage
Noise during traffic passage
4-5 Fair Joint is in place with debris. Broken seal in small areas with embedded debris
Joint nosing is cracked/ in bad condition with little or no reinforcing steel exposure
Small water leaks Noise during traffic passage
6-7 Good Joint is solidly in place with debris and no breaks in the seal
Joint nosing is in good condition with limited cracking and no deck steel exposure
No water leaks evident
Slight noise during passage of traffic
8-9 Nearly New Joint appears new with some debris which does not affect performance
Joint nosing is in good condition with no cracking and no deck steel exposure
No water leaks evident
Quiet during passage of traffic
10 New Joint has excellent appearance with no debris in joint
Joint nosing is in excellent /new condition
No water leaks evident
Quiet during passage of traffic
Other Symptoms
Overall Rating 1 2 3 4 5 6 7 8 9 10
57
Table 8.5 Polymer Modified Asphalt Joint Evaluation Scheme
Rating Condition Symptom Appearance Steel Plate Leakage Noise
0-1 Poor Joint is missing/fallen out completely
Missing steel plates Evidence of total water leakage due to holes, loose, torn, split, or hardened polymer material
Extreme noise during traffic passage
2-3 Bad Joint is partially in place
Loose and/or broken steel plates
Evidence of water leakage due to holes, loose, torn, split, or hardened polymer material
Noise during traffic passage
4-5 Fair Joint is in place with rutting and broken seal in small areas
Loose steel plates Small water leakage due to holes, loose, torn, split, or hardened polymer material
Noise during traffic passage
6-7 Good Joint is solidly in place with few breaks in the seal
Steel plates sufficiently intact and in place
No water leaks evident, but loose or hardened seal condition
Slight noise during passage of traffic
8-9 Nearly New Joint appears new with some breaks which does not affect performance
Steel plates in excellent condition
No water leaks evident
Quiet during passage of traffic
10 New Joint has excellent appearance
Steel plates in new condition
No water leaks evident
Quiet during passage of traffic
Other Symptoms
Overall Rating 1 2 3 4 5 6 7 8 9 10
58
CHAPTER 9
DATA ANALYSIS
1998 INDOT Roadway Management data was used for the analysis. The objective of the
data analysis was to compare the performance of each type of joint under the same
condition of age, traffic loading, and structure settlement. Through the analysis, the
statistic distribution of the joint types, their conditions and ages, and the related
parameter such as traffic on INDOT bridges, was also presented.
9.1 Simple Statistics
Table 9.1 shows the statistics of the numbers of the joints in the SW (south or west) end,
NE (north or east) end, and the interior end. It can be seen that I.A. joints, B.S. joints,
and S.S. joints account for most of the existing joints, making up 93% of the total number
of joints. There are not many interior joints, the percentage of which is only 8.3%.
Table 9.1 Joint Number Statistics
Joint Type A B H O P Q Total PercentageLocation South or West 1804 480 986 62 51 134 3517 45.9% North or East 1820 477 978 61 50 121 3507 45.8% Interior 405 150 32 13 6 33 639 8.3% Sub Total 4029 1107 1996 136 107 288 7663 100% Percentage 52.6% 14.4% 26.0% 1.8% 1.4% 3.8% 100%
A: B.S. Joint, B: S.S. Joint, H: I.A. Joint, O: XJS Joint, P: Poured Silicone Joint (in old I.A. Joint), Q:
Polymer Modified Asphalt Joint
Table 9.2 shows the quantity and the percentage of the condition (good, fair, poor) for
each type of joint and the statistics of the age and average daily traffic on it. The
distribution of the condition of each joint is plotted as shown on the pie chart in Figure
9.1. The statistics for each type of joint in each district is listed in Appendix H. The age
of each joint is obtained by subtracting the year in which a bridge with this joint was built
from the year of the inspection.
59
Table 9.2 Simple Statistics of the Joint Data
Joint Type Condition Quantity Percentage Age ADT
Good 1410 34.94% Mean 11.58 Mean 13549 B.S. Type Fair 1432 35.49% Std. Dev. 5.35 Std. Dev. 29024
Poor 1193 29.57% Median 11 Median 7104 Subtotal 4035 Max. 39 Max. 992572 Min. 0 Min. 0 Good 694 62.41% Mean 9.9 Mean 12362
S.S. Type Fair 279 25.09% Std. Dev. 7.14 Std. Dev. 18210 Poor 139 12.50% Median 9 Median 6896 Subtotal 1112 Max. 34 Max. 114440 Min. 0 Min. 0 Good 13 16.67% Mean 21.12 Mean 19531
Tooth Type Fair 53 67.95% Std. Dev. 8.19 Std. Dev. 31253 (Finger Joint) Poor 12 15.38% Median 24 Median 7536
Subtotal 78 Max. 31 Max. 127450 Min. 2 Min. 64 Good 9 20.93% Mean 20.72 Mean 6214
General Tire Type Fair 16 37.21% Std. Dev. 6.5 Std. Dev. 8123 (Trans flex Type) Poor 18 41.86% Median 22 Median 3783
Subtotal 43 Max. 28 Max. 35491 Min. 3 Min. 0 Good 0 0.00% Mean 22 Mean 885
Feldspar Type Fair 5 100.00% Std. Dev. 1 Std. Dev. 603 Poor 0 0.00% Median 21 Median 885 Subtotal 5 Max. 22 Max. 1311 Min. 20 Min. 458 Good 55 47.83% Mean 27.6 Mean 1491
Sliding Steel Plate Fair 56 48.70% Std. Dev. 15.33 Std. Dev. 3005 Poor 4 3.48% Median 27.5 Median 407 Subtotal 115 Max. 73 Max. 12505 Min. 0 Min. 58 Good 0 0.00% Mean 31.76 Mean 1460
Armor Type Fair 20 38.46% Std. Dev. 1.92 Std. Dev. 2728 (Two steel angles) Poor 32 61.54% Median 32 Median 290
Subtotal 52 Max. 34 Max. 9139 Min. 26 Min. 74 Good 1435 70.93% Mean 6.03 Mean 8309
IA Type Fair 391 19.33% Std. Dev. 6.43 Std. Dev. 10109 Poor 197 9.74% Median 4 Median 5441 Subtotal 2023 Max. 46 Max. 114440 Min. 0 Min. 1 Good 56 61.54% Mean 8.04 Mean 11267
Modular Type Fair 31 34.07% Std. Dev. 4.47 Std. Dev. 8333 Poor 4 4.40% Median 8 Median 9852 Subtotal 91 Max. 15 Max. 30308 Min. 0 Min. 1248
60
Joint Type Condition Quantity Percentage Age ADT
Good 27 19.15% Mean 25.63 Mean 4697 Open Joint Fair 87 61.70% Std. Dev. 5.93 Std. Dev. 5715
Poor 27 19.15% Median 26 Median 1752 Subtotal 141 Max. 35 Max. 19317 Min. 2 Min. 78 Good 93 65.49% Mean 2.66 Mean 227.6
Poured Dow Corning Silicone Fair 46 32.39% Std. Dev. 4.16 Std. Dev. 26401 Joint (wide width) Poor 3 2.11% Median 2 Median 12361
Subtotal 142 Max. 20 Max. 94860 Min. 0 Min. 0 Good 73 68.22% Mean 5.73 Mean 8548
Poured Silicone Joint Fair 23 21.50% Std. Dev. 10.62 Std. Dev. 8680 (narrow width - in old IA joints) Poor 11 10.28% Median 2 Median 5109
Subtotal 107 Max. 36 Max. 40501 Min. 0 Min. 21 Good 168 57.53% Mean 3.38 Mean 20461
Polymer Modified Asphalt Fair 62 21.23% Std. Dev. 4.34 Std. Dev. 25632 Expansion Joint Poor 62 21.23% Median 2 Median 12415
Subtotal 292 Max. 22 Max. 111620 Min. 0 Min. 100 Total 8236
Std. Dev.: Standard Deviation
61
Figure 9.1 Percentage Distribution of Joint Conditions
B.S. JOINT
Good35%
Fair 35%
Poor30%
S.S. JOINT
Good62%
Fair 25%
Poor13%
XJS JOINT
Good66%
Fair 32%
Poor2%
POURED SILICO N JOINT (IN O LD IA JOINTS)
Good69%
Fair 21%
Poor10%
PO LYMER MODIFIED JOINT
Good58%Fair
21%
Poor21%
I.A. JOINT
Good71%
Fair 19%
Poor10%
62
Table 9.3 shows the comparison of condition distributions for each type of joint at both
ends of a bridge. It shows that on the same bridge, the joint types and their conditions are
very similar at the NE and SW end. For instance, there are 1558 B.S. joints (A) that have
the same conditions at the both ends of bridges. This number accounts for 86.36% of the
total SW B.S. joints and 85.6% of total NE B.S. joints. S.S. joint (B) has a smaller
percentage, but the number of total S.S. joints is only 480. Table 9.4 shows the
percentage distribution of the conditions of each type of joint at different locations of the
bridge.
Table 9.3 Comparison of Joint Types and Conditions at Both Ends of Bridge
A B H O P Q SW VS. NE Fair 530 63 163 18 9 16 Good 586 208 673 35 34 60 Poor 442 25 72 0 4 19 Sub Total 1558 296 908 53 47 95 Total (SW) 1804 480 986 62 51 134 Percentage 86.36% 61.67% 92.09% 85.48% 92.16% 70.90% Total (NE) 1820 477 978 61 50 121 Percentage 85.60% 62.05% 92.84% 86.89% 94.00% 78.51%
Table 9.4 Percentage Distribution of Joint Conditions
Interior Joint
A B H O P Q G 90 22.22% 62 41.33% 5 16.13% 8 61.54% 2 33.33% 18 54.55% F 172 42.47% 66 44.00% 7 22.58% 5 38.46% 1 16.67% 11 33.33% P 143 35.31% 22 14.67% 19 61.29% 0 0.00% 3 50.00% 4 12.12% Total 405 100.00% 150 100.00% 31 100.00% 13 100.00% 6 100.00% 33 100.00%
NE Joint
A B H O P Q G 659 36.21% 316 66.25% 695 71.06% 38 62.30% 35 70.00% 71 58.68% F 633 34.78% 100 20.96% 190 19.43% 21 34.43% 11 22.00% 25 20.66% P 528 29.01% 61 12.79% 93 9.51% 2 3.28% 4 8.00% 25 20.66% Total 1820 100.00% 477 100.00% 978 100.00% 61 100.00% 50 100.00% 121 100.00%
63
SW Joint
A B H O P Q G 655 36.31% 311 64.79% 707 71.70% 41 66.13% 36 70.59% 75 55.97% F 627 34.76% 113 23.54% 194 19.68% 20 32.26% 11 21.57% 26 19.40% P 522 28.94% 56 11.67% 85 8.62% 1 1.61% 4 7.84% 33 24.63% Total 1804 100.00% 480 100.00% 986 100.00% 62 100.00% 51 100.00% 134 100.00%
From Table 9.1 through 9.4, several conclusions were made. First, it was very hard to
tell the performance of each type of joint just through the simple statistics since the joint
performance was influenced by its age, the traffic volume, or other factors. Second, since
there is only a small amount of interior joints, they can be excluded in the further
analysis. Finally, the types and conditions of joints at both ends of the bridge are almost
the same. Therefore, only joints at one end of each bridge (SW or NE) will suffice for
further data analysis. The joints on the SW end of the bridge are selected in this study.
The regression technique is used to analyze the relationship between the joint condition
and the influencing factors.
9.2 Regression Analysis
Regression analysis is a statistic approach that is used to understand how the dependent
variables are influenced by the independent variables. The first step of the analysis is to
acquire the influencing variables. Sixteen items from the management data were selected
as the independent variables and one item, joint condition, was selected as the dependent
variable since the objective is to understand how the joint condition is influenced by
factors such as age, traffic volume, settlement, etc. All of the selected variables and their
definitions, data patterns, and ranges are shown in Table 9.5. After developing the
regression equations for each type of the joint, a comparison of joint performance was
conducted based on the same conditions to establish which type of joint performs better.
The SAS computer program is used to perform the regression analysis and the computer
codes and output can be found in Appendix I.
Although the joints were in three locations on each bridge, i.e., interior, south or west,
and north or east, it was concluded from simple statistics that the joint types and
64
conditions at each end were almost identical and most bridges do not have interior joints.
Thus, only the joint condition at the SW (south or west) end of each bridge was used in
the next stage of analysis.
Table 9.5 Variables Selected for the Regression Analysis
No. Independent Variables Definition Range Pattern
1 SMA STRUCT-MATERAIL 0-9 Most concentrated on 1 and 2
2 SCN STRUCT-CONSTRUCTION 0-22 Most concentrated on 2 and 4
3 AMA APPROACH-MATERIAL 0-9 Most concentrated on 0 4 ACN APPROACH-
CONSTURCTION 0-22 Most concentrated on 0
5 TRD TRAFFIC-DIRECTION 0-3 Most concentrated on 1 and 2
6 SBR SPSTR-BEARING 0-9, N Most concentrated on 6,7, and 8
7 SIM SPSTR-IMPACT 0-9, N Most concentrated on 7 and 8
8 SBS SBSTR-SETTLEMENT 0-9, N Most concentrated on 7 and 8
9 INS SBSTR-INTERMD-SETTLE 0-9, N Most concentrated on 7 and 8
10 SKEW SKEW 0-99 Most concentrated on 0 11 LMS LENGTH-MAX-SPAN 12 SL STRUCTURE-LENGTH 13 BRW BRIDGE-ROADWAY-WIDTH 14 DW DECK-WIDTH 15 ADT ADT-OVER (AVARAGE
DAILY TRAFFIC) (VEHICLES/DAY)
16 AGE AGE
No. Dependent Variables Definition Range
1 COND BRIDGE-JOINT-COND-(SW, NE, or IN)
Good, Fair, Poor
65
9.2.1 Simple Regression Analysis
Although there are 16 independent variables, some of them may not significantly
influence the joint condition. By using simple regression analysis, the insignificant
variables can be eliminated. The levels of the response variable (Joint Condition) were
changed to 1, 2, and 3 from good, fair, poor, to accommodate the computer program
requirements.
Table 9.6 shows the variables selected and unselected for each type of joint after the
simple regression analysis. The selection criteria reflect its relationship with the
dependent variable and the significance level was set at 0.05. For instance, if a variable
was found not to be highly correlated with the joint condition, it was excluded in the
analysis, which means this variable does not have much influence on the dependent
variable, the joint condition. Table 9.6 illustrates that the variables selected for each type
of joint are quite different. The B.S. joint has the largest number of variables which
might be due to the fact that since the B.S. joint has the largest quantity of data, it is
easier to identify the relationships between the joint conditions and the independent
variables. The newer joint type, however, such as the Polymer Modified Asphalt joint,
has a shorter history of usage and less available data so the fewer variables are selected
than for the B.S. joint.
Table 9.6 Variables Selected by Simple Regression Analysis
Joint Type Selected variables Unselected variables B.S. ADT, AGE, DW SMA, SIM,
LMS, SMA, SCN, TRD, SBR, SIM, SBS, INS
SL, AMA, ACN
S.S. AGE, SIM SKEW, ADT, DW, SL, LMS, SMA, SCN, AMA, CAN, TRD, SBR, SIM, SBS, INS
I.A. ADT, AGE, SIM, SBS SKEW, DW, SL, LMS, SMA, SCN, AMA, CAN, TRD, SBR, INS
66
XJS LMS, AMA, ACN, SIM SKEW ADT AGE, DW, LMS, SMA, SCN, TRD, SBR, SBS, INS
Poured Silicone (in old I.A. joints)
SBS SKEW ADT, AGE, DW, SL, LMS, SMA, SCN, AMA, ACN, TRD, SBR, SIM, SBS, INS
Polymer Modified Asphalt joints
SKEW, AGE, LMS, SCN, TRD, SIM
ADT, DW, SL, SMA, AMA, CAN, SBR, SBS, INS
It should be noted that even though the S.S. joint has a relatively long history of usage
(the mean age is 11.58 years compared to 13.33 years of the B.S. joint), there are only
two variables selected. The reason might be that the selection of variables not only
depends on the relationships between independent and dependent variables but also the
relationships between the independent variables. Therefore, if two independent variables
are highly correlated, it is very likely that both of them will be excluded in the regression
analysis because it becomes more difficult to distinguish which variable is more
important. Therefore, another statistic approach, factor analysis, is used to solve the
correlation problems among the independent variables.
9.2.2 Factor Analysis
The primary purpose of the factor analysis is to define the underlying structure in a data
matrix. It addresses the problem of analyzing the structure of the correlation among a
large number of variables by defining a set of common underlying dimensions, known as
factors. The advantage of using factor analysis is its ability to condense the number of
independent variables by grouping the variables that are highly correlated. After
performing the factor analysis, three groups were identified. The name of each group and
the variables included are shown in Table 9.7. The first group is named settlement since
it consists of all variables related to settlement, such as structure impact, substructure
settlement, substructure bearing condition, and intermediate settlement. The second
group is named traffic loading since the included variables are average daily traffic, deck
width, and bridge roadway width, which are all related to traffic volume. The third group
is named the structure design and includes structure length, length max span, approach
67
material, and approach construction. Some variables, such as age, traffic direction, skew,
etc., were not included because they have little or no relationship with other variables and
thus can form an individual group. These individual variables will also be included in the
final regression analysis with the three groups (factors). The final goal is to find out the
coefficients of each factor and the individual variables. Comparisons can then be made
based on the coefficients of each joint to establish which one has better performance.
Details of the comparison process are explained in the next section.
Table 9.7 Factor Analysis Result
Factor 1 Factor 2 Factor 3 Individual
Variables Name Settlement Traffic loading Structure design Elements SBR, SIM,
SBS, INS ADT, DW, BRW
SL, LMS AMA, ACN AGE, SKEW, TRD, SMA, SCN
9.2.3 Logistic Regression Analysis
Different types of regression methods can be used to analyze the data. In this analysis,
the dependent variable, joint condition, has three levels (good, fair, and poor). This is
called the ordinal scale in Statistics and logistic regression is used to analyze this kind of
data. The advantage of logistic regression is that the procedure is simple and the results
can be obtained quickly and accurately. To simplify the analysis, the condition of good
and fair was combined together into one condition state. The advantage of doing this is
to show the distinct characteristic of poor condition vs. (good and fair conditions) since
poor was a very critical state in the joint performance. If a joint is rated as poor, INDOT
will take remedy measures on them. In addition, the binary responses (good and fair vs.
poor) of the dependent variable is much easier and efficient to analyze than the three
responses.
68
9.2.3.1 Interpretation of the Selected Factors
In the logistic regression analysis, it was found that two types of joints could not be
analyzed due to insufficient data. They are XJS and Poured Silicone (in old I.A. joints)
joints, both of which have only one and four joints rated as poor. Thus, the number of
poor joints is too small for the regression analysis to identify the relationship between
good and poor since most of the joints are good. Therefore, only four types of joints
remained in the final analysis and the result is shown in Table 9.8. For each type of the
joint shown in the table, the variables or factors selected for each joint were identified as
having a close relationship with the dependent variable, the joint condition. The
significance level of the selection is set at 0.1. There is no correlation problem among the
independent variables now since the factor analysis already grouped the correlated
variables together.
From the analysis results shown in Table 9.8, it was found that some factors and variables
were eliminated, such as structure design, structure construction, and structure material,
which can be reasonably explained. For example, the factor of structure design was not
included in the other three types of joints, except the Polymer Modified Asphalt joint.
This means the factor of the structure design, which includes structure length, length max
span, approach material, and approach construction, does not have significant influences
on the performance of most joints. This was substantiated by the expert interviews;
however, the influence of this factor is not significant when compared to that of age or
traffic.
Table 9.8 Logistic Regression Analysis Result
B.S. Joint (1804 observations) Factor Odds ratio Settlement 3.12 Traffic loading 0.651 Age 0.805
69
S.S. Joint (480 observations) Factor Odds ratio Settlement 1.564 Traffic loading 0.675 Age 0.848 I.A. Joint (986 observations) Factor Odds ratio Settlement 3.363 Age 0.736 Polymer Modified Asphalt Joint (134 observations) Factor Odds ratio Structure design 3.30 SMA, SIM 1.54
9.2.3.2 Interpretation of the Regression Coefficients
The odds ratio is defined as the ratio of the probabilities of good1 over poor. The
formula is: Odds Ratio = P(good)/(1-P(good)) = P(good)/P(Poor). Thus, if the ratio is
larger than 1, it means as the value of the independent variable gets larger, the chance of
becoming good over poor increases. The higher the ratio is, the greater the chance the
joint will become good rather than poor. For instance, if the settlement is selected as the
basis of comparing joint performance, the joint with the higher odds ratio has more
chances of becoming good over poor when the settlement index increases one unit.
However, if the ratio is less than 1, it means that as the value of the independent variable
increases, the chance of becoming good over poor decreases. Thus, if age is selected as
the basis of comparison, the joint with the smaller odd ratio (which is smaller than 1)
deteriorated faster. That is, the chance of becoming poor over good is higher. Figure 9.2
to Figure 9.4 show the performance curve based on each factor. The numbers shown
beside the vertical axis of the slope were derived by (1 – Odds Ratio).
1 In the logistic regression analysis, the condition Fair was combined into Good to fit a binary response regression model (which only has Good and Poor).
70
Figure 9.2 Performance Curve Based on Age
Figure 9.3 Performance Curve Based on Traffic Loading
Traffic Loading(x 1000)
OddsRatio
P(Good)/P(Poor)
40100
10.35 S.S.
B.S.
20 30
10.325
Age
OddsRatio
P(Good)/P(Poor)
40100
10.26
I.A.
S.S.
B.S.
20 30
10.195
10.152
71
Figure 9.4 Performance Curve Based on Settlement
9.3 Summary
The joint performance rankings based on each variable (the factor) are shown in Table
9.9. The higher ranking means this type of joint has a slower deterioration rate under the
influence of this factor. As seen from Figure 9.2 through Figure 9.4, the curve with the
flatter slope means the deterioration rate is slower and hence the joint has the better
performance. Thus, the historical data analysis clearly indicated that the S.S. joint
performed the best, B.S. joints the second, and I.A. joints the third, under the same
conditions of age, traffic loading, or settlement.
Since each joint includes different types of factors, not all of the joints can be compared.
For instance, traffic loading only appears in the B.S. joint and the S.S. joint, so only the
two of them can be compared based on traffic loading. This also means traffic loading is
not an important factor for the performance of the I.A. joint since the result of the
regression analysis shows it is not significant. For the Polymer Modified Asphalt joint,
the factor of structure design seems to have more influences on its performance since this
factor only appears for this type of joint.
Settlement
OddsRatio
P(Good)/P(Poor)
0123456789
1
3.363
1
3.121
1.564
I.A.S.S.
B.S.
72
Table 9.9 Joint Ranking Based on the Deterioration Rate
Ranking
Variable 1 2 3
Age S.S. B.S. I.A.
Traffic loading S.S. B.S. -
Settlement S.S. B.S. I.A.
73
CHAPTER 10
GUIDELINE OF POLICY DEVELOPMENT
Throughout the research, the goal was to produce a provision for the evaluation and use
of expansion joints on bridges in Indiana. Following are the recommendations of this
research for future policy development regarding the selection and evaluation of bridge
deck expansion joints, as well as suggestions for improving joint performance.
10.1 Selection of Bridge Deck Expansion Joints
In this study, five types of joints, B.S., S.S., I.A.(poured sealer and neoprene seal), XJS,
and Polymer Modified Asphalt Joints (LDI and PaveTech) were investigated. From the
questionnaire survey, it can be concluded that the S.S. joint is considered the most
reliable joint. The I.A. joint with a poured sealer is preferred over the same joint with a
neoprene seal, and the PaveTech joint is one of the least favored joints from both surveys.
The XJS joint was ranked well in the follow-up survey but evaluation of its long-term
performance is needed. From the expert interviews, it was learned that the Integral
Abutment joints (I.A.) are showing promising results with good performance and less
maintenance requirements. The XJS joints obtained some positive comments while
Polymer Modified Asphalt joints were less favored. The older joints, such as the B.S.
and S.S., are performing well but could be improved. Through the data analysis, the
performances of S.S., B.S., and I.A. joints were rated as first, second, and third under the
same conditions of age, traffic loading, and settlement. Other types of joints could not be
analyzed due to insufficient data.
The questionnaire survey results showed that the S.S. joint was better than the B.S. joint
in terms of the estimated joint life and the recommended joint types. The result of the
historical data analysis showed the performance of the S.S. joint was better than the B.S.
joint in terms of age, traffic loading, and settlement. The expert interviews showed that
the performance of S.S. joint and B.S. joint could be improved; however, the expert
interviews did not clearly reveal whether the S.S. or B.S. joint performs better. Literature
review showed the performance of the S.S. joint was slightly better than the B.S. joint in
74
the overall rating. Therefore, from the evaluations of the previous four categories, the
S.S. joint is favored than the B.S. joint in overall in this study.
Synthesizing the above results, S.S. and I.A. joints are recommended for their overall
performance. I.A. joints with poured sealers are better than those with neoprene seals.
The B.S. joint could perform well if material such as seals could be properly selected and
the installation correctly done. The XJS joint is new and has a limited performance
history so this type of joint requires more research and observation to adequately judge its
performance. Finally, the Polymer Modified Asphalt joints, including LDI and
PaveTech, are the least favored joints from the investigation conducted in the research.
10.2 Evaluation of the Existing Joint Conditions
Currently INDOT only uses three conditions to evaluate the existing joints, i.e., good,
fair, and poor. The drawbacks of these evaluation criteria are that the definitions of these
conditions are not clear and thus each condition could be subjectively decided by the
bridge inspectors. The following is a recommendation for evaluation of existing joint
conditions.
1. Using the new evaluation criteria
The new evaluation criteria were discussed in Chapter 8. These new criteria were
assembled from the results of the questionnaire survey and the expert interviews. The
advantages of these new criteria are that more detailed levels of joint conditions are
defined and each level is represented by a numerical value. This can make the
evaluation less subjective by the inspector and the numerical value will simplify the
data analysis in the future.
75
2. Inspection training
From the results of the questionnaire surveys and interviews with bridge experts, the
answers regarding joint problems and their causes were very different among bridge
inspectors. This could be due to different years of experiences and different personal
opinions. With better inspection training, subjective opinions among inspectors could
be minimized and more common points of view could be reached.
10.3 Improvement of the Joint Performance
Recommendations to improve the performance of the types of joints investigated in this
research are as follows:
1. B.S. Joint
Spalled and cracked concrete was selected as one of the most severe problems for this
type of joint. One solution to this problem would be to add sealer to concrete to increase
its resistance to freezing and thawing, and thereby reduce spalling and cracking. Since
the seal could become hardened and will not expand back to its original thickness, the
seal should be tested and properly selected before installation.
2. S.S. Joint
Debris seems to be the major problem of this type of joint. The joint should be designed
with self-flushing capabilities, such as sufficient slope in the design or a larger curb
opening. Sometimes armor angle breaks under wheel loading can catch on snowplow
blades and create more maintenance problems. It is better to use non-corroding extrusion
and larger diameter bolts to hold down the anchor blocks.
76
3. I.A. Joint (Poured Sealer)
It appears there are no major problems with this type of joint, although it was found that
joint materials do not always completely fill the opening. The notch should be made
deeper and filled with silicone. Beveled edges can reduce concrete spalling due to wheel
loads. To reduce spalled and cracked concrete 5 to 10 feet from the end of the deck,
approach slabs should be tied to the deck to eliminate movements.
4. I.A. Joint (Neoprene Seal)
The problems and suggested improvements of this type of joint are similar to those for
the previous I.A. joint. However, the survey results show its performance is worse than
the one with a poured sealer.
5. XJS Joint
This type of joint has several problems. The epoxy materials were found to come in
contact with traffic, which causes holes in the seals. This could be due to installing it too
high, structure expansions causing it to shove upwards, or hot weather. The polymers
should be kept slightly below the top of deck elevation and the chamfer should be large
enough to prevent spalling of the nose. Silicone thickness should be placed correctly and
the silicone material mixed correctly.
6. LDI Joint
Several problems were found with this type of joint. Polymer modified asphalt materials
were found missing with steel plates rusted and cracked. The asphalt materials
experience shoving and rutting during hot weather, and there were cracks in the shoulder
area. The mixing of materials was not up to the standard quality. Thus, the bonding
between the header and adjacent concrete could be improved by using better materials.
77
The material testing should be done before installation. The proper selection of locations
where heavy truck traffic is not present or where large expansion is not required may
improve the joint performance.
7. PaveTech Joint
The problems and improvements of this joint are similar to those of LDI joints.
However, its polymer modified asphalt material were found softer than that of LDI and
hence the problems of shoving and rutting were more serious.
78
CHAPTER 11
CONCLUSION
INDOT has encountered problems with the poor performance of bridge expansion joints,
which have led to increase joint replacements and maintenance. This research attempted
to find the sources of the problems and to develop policy for the corrective measures.
The problems that INDOT has faced with the joints include the misplacement of the joint,
misalignment, deterioration, rutting, or leaking of joint materials. These problems could
be due to aging of the joint, traffic volume, weather, or installation quality. All of the
aforementioned problems and causes have been investigated and quantified through the
questionnaire surveys, site visits, expert interviews, and analysis of INDOT historical
data.
Two questionnaire surveys and a follow-up survey were conducted; the first one and the
follow-up survey was in Indiana only and the second one included the four surrounding
states of Illinois, Ohio, Michigan, and Kentucky. Interviews were also conducted with
bridge inspectors and engineers in Indiana and the four surrounding states. The joints
studied in this research are B.S., S.S., XJS, I.A., and Polymer Modified Asphalt joints.
11.1 Results
The results of the study were obtained by conducting the questionnaire surveys, data
analysis, and expert interviews. In this section, the result summary of each is presented
and comparisons are made among these results.
11.1.1 Questionnaire Survey
The result of the In-State questionnaire survey on the estimated joint life is as follows:
79
Table 11.1 Estimated Life of Each Type of Joint
Joint Type S.S. B.S. I.A. XJS LDI
Estimated
Life
11.9 11.706 8.728 5.19 3.502
The survey of other states DOT’s generally confirmed the In-State results. Although the
estimated life of the same joint is a little different in both surveys, the ranking of the joint
by the length of the estimated life is very similar.
However, caution should be used interpreting the results. Since B.S., S.S., and I.A. joints
have a longer performance history, their estimated life is certainly longer than the other
joints. Most bridge inspectors expressed their concerns that they did not have much
experience with the newer types of joints, i.e., XJS, LDI, and PaveTech, and it was
therefore difficult for them to estimate their life.
The ranking from the questionnaire survey on the recommended better joints is shown in
the following table (averaging the ranking from both methods in Table 5.4):
Table 11.2 Summarized Ranking for Recommended Types of Joints
Ranking 1 2 2 4 5 6 7
Joint type S.S. I.A.
(Poured
sealer)
B.S. I.A.
(Neoprene
seal)
XJS LDI PaveTech
Finally, the ranking of the performance of each type of joint in riding quality, water
leakage, noise, and difficulty of maintenance from the follow-up survey is shown in
Table 11.3. The results shown in the table generally confirm the results of the previous
questionnaire surveys. The performance of each type of joint, from good to worst, was
shown in the pattern of the S.S., B.S., I.A., and the LDI joint. Although the XJS joint
80
received good ranking in most categories, due to its limited history of usage, its long-term
performance should be evaluated for a longer period of time.
Table 11.3 Performance of Joints based on Specific Categories
Ranking Riding Quality Water Leakage Noise Maintenance
XJS S.S. XJS XJS & S.S.
S.S. LDI S.S. B.S.
I.A. B.S. B.S. LDI
B.S. & LDI XJS I.A. I.A.
Good
Worse I.A. LDI
11.1.2 Data Analysis
The analysis on INDOT Roadway Management data yielded the following ranking in
Table 11.4
Table 11.4 Joint Ranking based on the Deterioration Rate
Ranking
Variable 1 2 3
Age S.S. B.S. I.A.
Traffic loading S.S. B.S. -
Settlement S.S. B.S. I.A.
Based on the results, the S.S. joint had the best performance; the B.S. joint was second;
and the I.A. joint was third based on the same conditions of age, traffic loading, and
settlement.
81
The results of the Roadway Management data analysis are very similar to the results of
the questionnaire survey. However, the result of data analysis is only limited to the S.S.,
B.S., and I.A. joints. Other types of joints could not be rated due to insufficient data.
11.1.3 Expert Interviews
This part of research was mainly performed by telephone and personal interviews.
During these interviews, there was common consensus among all investigated DOTs that
the older joints, such as the B.S. and S.S., are performing well, though they still have
room for improvement. The experts also indicated that the I.A. and XJS joints have good
life spans and lower maintenance costs. It is likely that the usage of these joints will
increase once it is learned that they are superior to the other joints. Meanwhile, many
interviewees commented that the Polymer Modified Asphalt Expansion joints cause
many problems with maintenance and have short life spans.
From the expert interviews it was found that maintenance strategies are not systematic in
all of the investigated states. Maintenance efforts usually depend on the amount of time
and funding allocated, but the resources are usually depleted before all of the projected
work is completed.
11.2 Limitations
The research does have limitations. In the questionnaire surveys, although the expert
opinions of the bridge inspectors were collected, each inspector’s opinion could be
subjective. Second, the number of survey responses may not be adequate to get an
effective result. The number of responses to the second survey was only 32. If more
responses can be obtained, the result might be more objective and accurate. Finally, the
quality of the survey result also depends on the design of the questionnaire. Although the
questionnaires were designed to obtain as many opinions as possible from the inspectors,
some questions may not be clear or easy for the inspectors to answer. Thus, the answers
from the survey may not be appropriate or the response rate was low due to the
complexity of answering the questions.
82
The limitation of the data analysis is the quantity and quality of the data. There needs to
be enough data for good analysis and the data should be accurate enough to produce a
useful result. In this research, XJS joints and Polymer Modified Asphalt joints did not
have enough historical data for analysis. In addition, since the condition rating is
subjective, the results of the analysis may not represent the actual performance of each
joint. The limitation of the interviews is similar to the questionnaire survey, the number
of interview conducted, the people who were interviewed, and the information experts
were willing to provide all influenced the results of the interview.
11.3 Recommendations and Implementation for Future Work
Following are the most important recommendations for future work. The order of the list
does not represent the order of importance.
1. Selection of better joints for use
From the research result, S.S. and I.A. joints were shown to have better performances
and are thus recommended to be continually used. The B.S. joint could perform well
if materials such as seals are properly selected and the installation correctly done.
Further, it should be noticed that the I.A. joint with poured sealers performs better
than the one with neoprene seals. The XJS joint was rated well in the follow-up
survey but its long-term performance needs to be evaluated.
2. Cautions on using joints with poor performance
The Polymer Modified Asphalt Joints were the least favored joints in the
investigation. Although they have good ridibility, do not require flushing, and are not
damaged by snowplow blades, their overall performance is poor according to the
survey conducted. If they will be used in the future, their use is recommended in
locations where the truck traffic is light and the bridge expansion/contraction range is
small.
83
3. General recommendations for improving joint performance
Almost all of the severe problems for each type of joint are related to the seal and
concrete, mainly holes in the seal, and hardened, cracked, loose, or torn seals, and
spalled or cracked concrete. The causes of these problems could be traffic loading,
snowplow damage, weather, poor installation, inferior materials, and incorrect
selection of the joint type.
Several recommendations are proposed for improving joint performance. Coating
concrete with sealers may reduce the spalling and cracking. The seal should be tested
before installation. Whenever it is feasible, a larger curb opening or a sufficient slope
should be provided so that rain can flush the joint clear. The use of a specialty
contractor to install the joints would also enhance the installation quality and joint
performance.
4. The Feasibility of Using the Warranty Clauses
Some states include the warranty clauses in the pavement or bridge painting contract.
In some respects, the problems of joints are similar to those of the pavement and
bridge painting since their performance is all subject to the influences of the
environment and the installation quality. The survey results indicate that the
workmanship plays an important role in joint performance. Thus, the advantage of a
warranty clause is that the contractor or manufacturer becomes accountable for the
product’s performance and the installation quality could improve as a result.
If a warranty clause is used, three items must be defined clearly: the scope of
warranty, the warranty period, and the performance and payment bond. To reach a
well-defined warranty scope, the following also needs to be considered: (1) a clear
definition of the defects that the poor workmanship or poor product quality may
cause, (2) the method of measuring the degree of severity for all the predefined
84
defects, and (3) the limit that identifies the contractor’s or manufacturer’s
involvement in the occurrence of the defect (Chang and Georgy 1999).
5. The Testing of the Joint Materials
From the interviews, it was found that some joints are not tested before installation,
and the material quality and properties are judged only on the documentation
provided by the manufacturers. It is recommended that all types of joints be tested
before their use and the testing data stored for future reference.
6. Proposed Evaluation Schemes
The evaluation schemes on in-service expansion joint systems were developed. The
criteria of general appearance, condition of anchorage, debris accumulation, water
tightness, surface damage, noise under traffic, ease of or need of maintenance and/or
others were established. The schemes were designed to achieve a more objective
evaluation process.
85
REFRENCES 1. The American Association of State Highway and Transportation Officials. (1976).
AASHTO Standard Specifications for Highway Bridges, AASHTO, Washington, D.C. 2. Aktan E., Nims D., Parvin A., and Subramaniam K., “Analysis of Elastomeric
Bearings in an Instrumented Bridge System”, Fourth World Congress on Joint Sealants and Bearing Systems for Concrete Structures, ACI, 1996.
3. American Concrete Institute. (1996). Fourth World Congress on Joint Sealants and
bearing Systems for Concrete Structures, Atkinson, B., Editor, ACI. 4. Benson, K., Bridge Deck expansion Joint Evaluation, July 1986, Report No.
FHWA/AR-86/006. 5. Brinckerhoff, P. (1993). Bridge Inspection and Rehabilitation: A Practical Guide,
John Wiley & Sons, Inc., New York, N.Y. 6. Burke M., "Flawed Assumptions and the Failure of Bridge Deck Joints and
Bearings", Fourth World Congress on Joint Sealants and Bearing Systems for Concrete Structures, ACI, 1996.
7. Busch G. and Monroe D., “Improvements in Expansion Joint Sealing Performance for
Parking Structure Applications”, Fourth World Congress on Joint Sealants and Bearing Systems for Concrete Structures, ACI, 1996.
8. Chang, L. and Georgy M. (1999). Warranty clauses for INDOT Steel Bridge Paint
Contracts, Steel Bridge Protection Policy, Volume V, Final Report, Report No. FHWA/IN/JTRP-98/21.
9. Costa, J. and Mirambell E., “Prediction of Thermal Movements in Highway Bridges
and Their Influence on the Design of Joints and Bearings”, Fourth World Congress on Joint Sealants and Bearing Systems for Concrete Structures, ACI, 1996.
10. Dahir, S. and Mellot, D., Bridge Deck Expansion Joints, December 1985, Report No.
FHWA/PA-85/023. 11. Department of Transport. (1989). “The Performance of Concrete in Bridges: a survey
of 200 highway bridges”, HMSO, London. 12. Fincher, H., Evaluation of Rubber Expansion Joints for Bridges, Final report, Report
No RTC-83-1, Indiana Department of Highways, January, 1983. 13. Fincher, H., Evaluation of Rubber Expansion Joints for Bridges, Eighth Annual
Progress Report, Indiana State Highway Commission, February, 1980.
86
14. George P. R., Performance of Bridge Deck Expansion Joints, Summary report, Report No FHWA-SA-91-010, Federal Highway Administration, October, 1990.
15. Gulen, S., Experimental Rubber Expansion Joints, Annual report, Indiana Department
of Highways, February, 1982 16. Gulen, S., Rubber Expansion Joints, Annual report, Indiana State Highway
Commission, March, 1980. 17. Hamilton, C. D., Bridge Deck Expansion Joints, Final Report, July 1986, Report No.
FHWA/ME/TP/84/04. 18. Hunt, V., Helmicki, A., and Aktan, E. (1997). "Instrumented monitoring and
nondestructive evaluation of highway bridges." Infrastructure Condition Assessment: Art, Science, and Practice. Proceedings of the conference sponsored by the facilities management Committee of the Urban Transportation Division of the American Society of Civil Engineers, ASCE, pp.121-130.
19. Korr, R., Buba, J., and Kogut, G. (1983). "Bridge rehabilitation programming by
using infrared techniques, bridge inspection and rehabilitation." Transportation Research Record 899, National Academy of Sciences.
20. Kuo S. S. and Waddell M., “Performance of Bridge Deck Expansion Joints by Large-
Scale Accelerated Testing Apparatus”, Fourth World Congress on Joint Sealants and Bearing Systems for Concrete Structures, ACI, 1996.
21. Lee, D. J. (1994). Bridge Bearings and Expansion Joints, 2nd edition, E & FN SPON,
London, UK. 22. Ludlow, B., Bridge Expansion Joints, Independent Study Report, Purdue University,
November 1999. 23. Minkarah, I., Weisgerber, F., and Cook, J., Bridge Deck Expansion Joints, September
1986, Report No. FHWA/OH-87/006. 24. National Cooperative Highway Research Program. "Bridge Deck Joints." Synthesis
of Highway Practice 141, 1989. 25. Inter-Office Communication, Ohio Department of Transportation, 1995 26. Price, A. W. and Simonsen, J. E., Evaluation of Bridge Expansion Joints, August
1986, Report No. FHWA/MI-86/01. 27. Richard J. B. and Bruce W. A., "A New Generation of APJ Design: The Cold Plug
Joint", Fourth World Congress on Joint Sealants and Bearing Systems for Concrete Structures, ACI, 1996.
87
28. Ronald J. W. and Gary, A. B., "Finger Joints: A Further Evaluation utilizing Results of a Field Condition Survey", IBC-87-17.
29. Sabir H. D. and Dale B. M., Bridge Deck Expansion Joints, Research Project No. 83-
37, Pennsylvania DOT, December 1985. 30. Shubinsky, G. (1994). "Application of Optical Imaging Method for Bridge
maintenance and Inspection." ITI Technical Report No. 4. 31. Stewart C. W., "A Half-Century of Involvement with Joints and Bearings and Some
Lessons Learned", Fourth World Congress on Joint Sealants and Bearing Systems for Concrete Structures, ACI, 1996.
32. The American Association of State Highway and Transportation Officials. (1976).
AASHTO Manual for Bridge Maintenance, 1st Edition, AASHTO, Washington, D.C., pp. 87-126.
33. The American Association of State Highway and Transportation Officials. (1983).
AASHTO Manual for Maintenance Inspection of Bridges, AASHTO, Washington, D.C.
34. Thomas H. I. and Edgar E. C., Modular Expansion Joints and Deck Drains, Report
No. KTC-89-2, Kentucky Transportation Center, March 1989. 35. Thompson, L., and Westermo, B. (1996). "Development of smart structural
attachment fixtures." Proceedings of SPIE- The International Society for Optical Engineering. 2719, pp.90-101.
36. U.S. Department of Transportation. (1970). Bridge Inspector's Manual, Federal
Highway Administration, Washington, D.C. 37. U.S. Department of Transportation. (1995). Recording and Coding Guide for the
Structure Inventory and Appraisal of the Nation’s Bridges, Federal Highway Administration, Report No. FHWA-PD-96-001.
38. Wasserman, E. P., "Jointless Bridge Decks." Engineering Journal, American Institute
of steel construction, Third Quarter, 1987. 39. Watson, S. C. (1972). “A review of past performance and some new considerations in
the bridge expansion joint scene.” Paper presented to regional meetings of the AASHO Committee on Bridges and Structures, Spring, 1972.
40. Weishahn, L., Bridge Deck Expansion Joints, Final Report, July 1986, Project No.
DTFH71-84-4505-NE-04.
APPENDIX A Questionnaire of the First Survey
12/10/98
A1
INVESTIGATION OF BRIDGE DECK EXPANSION JOINTS Objective: The deck expansion joints are among the smaller elements of a bridge structure but they could incur costs higher than anticipated because of frequent maintenance and repair problems such as deterioration of concrete around bridge seats on the piers and on the abutments. Thus, in order to get more insight into the performance of the joints, a study including field investigation and data collection is being conducted. This questionnaire is a part of this study. It is designed to quantify the problems and causes related to the bridge deck expansion joints, and to obtain feedback from bridge engineers and inspectors. It is hoped that in this way better understanding of the performance of the joints can be obtained, and it serves as the future reference of the selection criteria for the different types of joints. Introduction: There are four parts in this questionnaire. Part I is a simple investigation of your background. Part II is the statement of problems related to the different types of joints. Part III is the statement of causes of the problems listed in Part II. Finally, Part IV is your recommendation. Since the list of choices in the questionnaire may not be very comprehensive, please write your own answers if you can not find them from the list. If you do not have experience with one of the types of the joints, simply answer with question mark. Part I: Background 1. How many years have you worked as an inspector? ________years 2. How many years have you worked as an inspector for INDOT? ________ years 3. What kind of position do you have? _______
a. Bridge Engineer b. Inspector c. Assistant Inspector d. Others (specify)__________
4. Which district are you in? ________
a. Crawfordsville b. Fort Wayne c. Greenfield d. La Porte e. Seymour f. Vincennes
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Part II: The Problems Associated with the Bridge Deck Expansion
Joints The following pages list possible problems for each type of the expansion joint. They are B.S. joint, S.S. joint, I.A. joint, poured Dow silicone (XJS) joint, and LDI – polymer modified asphalt joint. Please rank the three most severe problems by 1, 2, and 3 for each type of joint. 1 represents the most severe problem, 2 is the next, and 3 is the least severe. 1. B.S. Joint
Loose, torn, split, cracked, damaged, hardened seals
Damage of epoxy fillers or adhesive lubricants causing separation of the joint material from the joint face Accumulation of debris and incompressible materials in the seals Some components of the joint are missing
Cracked and spalled concrete, and rusted or exposed reinforcement steel or structural steel in the deck joints substrate Evidence of water leakage on the underside of the deck or at the curbline Evidence or noise during the passage of vehicles over the joint
Restriction on freedom of joint movement causing problems such as transverse movements of the deck Evidence of rotation, tilting, or settlement of joints Incorrect joint opening and alignment Deterioration along bearing areas on the pier caps and on the columns Poor ridebility Inadequate skid resistance Others __________________________________________________________
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A3
2. S.S. Joint
Loose, torn, split, cracked, damaged, hardened seals, or holes in seals
Damage of epoxy fillers or adhesive lubricants causing separation of the joint material from the joint face Accumulation of debris and incompressible materials in the seals
Loose, rusted, cracked, missing, or damaged steel plates, shapes, anchorage, bolts, nuts, holddown bars, and other metal components Others parts missing in addition to metal components
Cracked and spalled concrete, and rusted or exposed reinforcement steel or structural steel in the deck joints substrate Evidence of water leakage on the underside of the deck or at the curbline Evidence or noise during the passage of vehicles over the joint
Restriction on freedom of joint movement causing problems such as transverse movements of the deck Evidence of rotation, tilting, or settlement of joints Incorrect joint opening and alignment Deterioration around bearing areas on the pier caps and on the abutments Poor rideability Cracked or damaged welding Inadequate skid resistance Others___________________________________________________________
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A4
3. I.A. Joint
Loose, torn, split, cracked, damaged, hardened seals, or holes in seals Damage of epoxy fillers or adhesive lubricants causing separation of the joint material from the joint face Some components of the joint are missing
Cracked and spalled concrete, and rusted or exposed reinforcement steel or structural steel in the deck joints substrate Evidence of water leakage on the underside of the deck or at the curbline Evidence or noise during the passage of vehicles over the joint
Restriction on freedom of joint movement causing problems such as transverse movements of the deck Evidence of rotation, tilting, or settlement of joints Incorrect joint opening and alignment Deterioration around bearing areas on the pier caps and on the abutments Poor rideability Inadequate skid resistance Others___________________________________________________________
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A5
4. Poured Dow Silicone Joint (XJS)
Loose, torn, split, cracked, damaged, hardened seals, or holes in seals Damage of epoxy fillers or adhesive lubricants causing separation of the joint material from the joint face Accumulation of debris and incompressible materials in the seals Loose, torn, split, cracked, damaged, or hardened nosing materials Backer rods fall off Some parts missing in addition to backer rods
Cracked and spalled concrete, and rusted or exposed reinforcement steel or structural steel in the deck joints substrate Evidence of water leakage on the underside of the deck or at the curbline Evidence or noise during the passage of vehicles over the joint
Restriction on freedom of joint movement causing problems such as transverse movements of the deck Evidence of rotation, tilting, or settlement of joints Incorrect joint opening and alignment Deterioration around bearing areas on the pier caps and on the abutments Poor rideability Inadequate skid resistance Others___________________________________________________________
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A6
5. LDI – Polymer Modified Asphalt Joint
Loose, torn, split, cracked, damaged, hardened seals, or holes in seals (polymer material) Damage of epoxy fillers or adhesive lubricants causing separation of the joint material from the joint face
Loose, rusted, cracked, missing, or damaged steel plates
Other parts missing in addition to metal components
Cracked and spalled concrete, and rusted or exposed reinforcement steel or structural steel in the deck joints substrate
Evidence of water leakage on the underside of the deck or at the curbline
Evidence or noise during the passage of vehicles over the joint
Tracking and flowing of polymer during hot weather
Restriction on freedom of joint movement causing problems such as transverse movements of the deck
Evidence of rotation, tilting, or settlement of joints
Incorrect joint opening and alignment
Deterioration around bearing areas on the pier caps and on the abutments
Poor rideability
Inadequate skid resistance
Others___________________________________________________________
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A7
Part III: Causes of the Problems of the Bridge Deck Expansion Joints The following list consists of possible causes contributing to the problems associated with the bridge deck expansion joints. 1. Natural Forces
1.1 Rain 1.2 Sun 1.3 Snow 1.4 Dust 1.5 Ozone 1.6 Temperature changes 1.7 Moisture 1.8 Carbon dioxide 1.9 Ultraviolet rays
2. Vehicle Loading
2.1 Traffic density and axle loading – live loads 2.2 Traffic-induced movements 2.3 Traffic-induced vibration
3. Bridge structure
3.1 Camber growth 3.2 Fatigue of the metal components 3.3 Lateral movement, such as abutment tilting or embankment movement 3.4 Abutment settlement 3.5 Approach slab movement and settlement 3.6 Excessive shrinkage, creep, deflection, or rotation in deck slabs 3.7 Displacement of bearings 3.8 Insufficient size or imbedment of anchorage systems
4. Design
4.1 Improper design of the joint (e.g., unarmored joint edges) 4.2 Improper selection of joint type 4.3 Improper selection of materials or using inferior quality of materials in the joint (
e.g., seals are too hard or soft, sizes of seal or wall thickness are not adequate) 4.4 Poor or faulty drainage details 4.5 Defective or ineffective waterproofing 4.6 Insufficient clearance between the top of the deck and the top of the joint materials 4.7 Limited access to bearing shelves for maintenance 4.8 Difficulties of replacement/repair 4.9 Difficulties of cleaning
12/10/98
A8
4.10 Improper mix preparation, cure, compaction, shrinkage ,or thickness of surfacing and hand mixed materials
4.11 Poor design and performance of bearings 4.12 Unacceptable range of movements and end rotations of the deck 4.13 Incorrect position of bearing 4.14 Incorrect elastic modulus of the joints 4.15 Different coefficients of expansion of concrete and epoxy mortar casing the shear
forces on the bond plane 4.16 The exothermic action of epoxy mortar under cure producing shrinkage stresses 4.17 Skewed bridge structures 4.18 Lack of detailed drawings for the installation of joints
5. Construction
5.1 Poor installation 5.2 Inappropriate temperature in which the joint was being installed 5.3 Inadequate site preparation 5.4 Poor workmanship 5.5 Inadequate bedding 5.6 Inadequate bond 5.7 Inadequate anchorage 5.8 Failure of the fixings of other steel components 5.9 Looseness and pounding 5.10 Poor horizontal alignment 5.11 Poor vertical alignment (The joint is not at the proper level or not constructed in
the same plane as the bridge deck) 5.12 Improper construction of the joint gap 5.13 Seal punctures during installation resulting in tears later
6. External Forces
6.1 Simple wear and tear 6.2 Deicing chemicals (e.g. salts) 6.3 Industrial pollutants 6.4 Cement alkalis 6.5 Petroleum derivatives 6.6 Grit 6.7 Detritus 6.8 Debris 6.9 Vegetation growth near the curbs
7. Others
7.1 Poor maintenance 7.2 Poor inspection 7.3 Poor fabrication of joints
12/10/98
A9
7.4 Deteriorated bonding agents 7.5 Deteriorated bituminous materials 7.6 Vandalism
8. Other causes not included in the list (please specify)
8.1 __________________________________________________________________
8.2 __________________________________________________________________
8.3 __________________________________________________________________
Questions: For each type of the joints, please select three most possible causes from the list above that contribute to each problem you listed for the five joints in Part II. For example, if the problems of the bridge deck B.S. Joints are: _______Loose, torn, split, cracked, damaged, hardened seals _______Evidence of water leakage on the underside of the deck or at the curbline _______Deterioration along cap areas and beam ends Then you could fill out three most possible causes (numbers only in your answers) as follows: B.S. Joint
_________________, ____________, ______________
• Multiple causes (numbers) can be specified in each blank for a problem if these causes have equal weights
Answers: B.S. Joint
________, ________, ________
S.S. Joint
_______, ________, ________
I.A. Joint
________, ________, ________
4.12 (Unacceptable range
of movements and end rotations of the
deck)
6.2 (Deicing
chemicals (e.g. salts))
6.1 (Simple wear
and tear)
1 2 3
12/10/98
A10
Poured Dow Silicone Joint (XJS Joint)
________, ________, ________
LDI - Polymer Modified Asphalt Joint
________, ________, ________
12/10/98
A11
Part IV: Recommendation (a) Based on your observations, what are the advantages of each type of the joints?
Please select three major advantages of each type of the joints from the list below. Write your own answers if you can not find them from the list. Write them from the most important one to the least important one.
Advantages: a. Simple design and easy to specify b. Versatile – could be used in different sizes of bridge c. Easy to install d. Easy maintenance and repair e. Rapid curing f. Durable and trouble free g. Long performance history h. Few debris accumulated in the joint i. Strong seal j. Water tight k. Smooth ride l. Strong mechanical property m. Low construction cost n. Excellent weathering properties o. Resilient filler p. Eliminating time consuming and costly shop drawings
q. Others_______________________________________________________________
Answers: B.S. Joint
________, ________, ________
S.S. Joint
_______, ________, ________
I.A. Joint
________, ________, ________
Poured Dow Silicone Joint (XJS joint)
________, ________, ________
LDI - Polymer Modified Asphalt Joint
________, ________, ________
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A12
(b) The following list shows some possible improvements on the service life of the joints. 1. Removing the damaged parts and installing new ones 2. Repairing or modifying the joint openings 3. Armoring - protection against live-load impact 4. Improving joint drainage system 5. Arranging surface slopes and gully positions 6. Selecting a correct type of joint 7. Better installation process 8. Using rubber snowplow blades in the snow removal equipment 9. Improving the bridge design 10. Improving the joint design 11. Promoting the design of jointless bridge decks 12. Detailed installation plans provided by the manufacturer or the designer 13. Using specialty contractors to install the joints 14. Making manufacturers or contractors responsible for the installation and maintenance
of the joints 15. Regular and frequent inspection 16. Regular and frequent maintenance 17. A larger curb opening that flush themselves clear 18. Others
a. __________________________________________________________________
b. __________________________________________________________________
c. __________________________________________________________________
Please select three most possible ways to improve the service life of each joint. Write them from the most important one to the least important one. B.S. Joint
________, ________, ________
S.S. Joint
________, ________, ________
I.A. joint
________, ________, ________
Poured Dow Silicone joint (XJS joint)
________, ________, ________
LDI - Polymer Modified Asphalt Joint
________, ________, ________
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A13
(c) Based on your experience, how many years in average did each type of the joint last after it was installed?
1. B.S. joint: ________ years 2. S.S. joint: ________years 3. I.A. joint: _________years 4. Poured Dow Silicone joint (XJS joint): _______years 5. LDI - Polymer Modified Asphalt Joint: _______years
Any other comment on each joint:
________________________________________________________________________
________________________________________________________________________
________________________________________________________________________
________________________________________________________________________
________________________________________________________________________
________________________________________________________________________
________________________________________________________________________
Any suggestion on the design of the questionnaire:
________________________________________________________________________
________________________________________________________________________
________________________________________________________________________
________________________________________________________________________
________________________________________________________________________
________________________________________________________________________
________________________________________________________________________
This concludes the questionnaire; please review your responses and ensure you have answered all questions. Thank you for your participation.
APPENDIX B Result of the First Survey
B1
B.S. JOINT (survey #1) 1. Problem
Rank Symptom
1 Cracked and spalled concrete,
and rusted or exposed
reinforcement steel or structural
steel in the deck joints substrate
2 Deterioration along bearing
areas on the pier caps and on the
columns
3 Loose, torn, split, cracked,
damaged, hardened seals
2. Cause
Problems Cause 1 Cause 2 Cause 3
Cracked and spalled
concrete, and rusted or
exposed reinforcement
steel or structural steel in
the deck joints substrate
Traffic density and axle
loading –live loads
Deicing chemicals (e.g.,
salts)
Age and material failure
Deterioration along bearing
areas on the pier caps and
on the columns
Deicing chemicals (e.g.
salts)
Improper design of the
joint (e.g., unarmored
joint edges)
Rain
Loose, torn, split, cracked,
damaged, hardened seals
Debris Traffic – induced
movements and
vibration
Lateral movement, such as
abutment tilting or
embankment movement,
abutment settlement, and
approach slab movement and
settlement
B2
3. Strength
Rank Item
1 Simple design and easy to specify
2 Low construction cost
3 Long performance history
4. Improvement
Rank Item
1 Promoting the design of jointless
bridge decks
2 Removing the damaged parts and
installing new ones
3 Armoring – protection against live-
load impact
B3
S.S. JOINT (survey #1)
1. Problem
Rank Symptom
1 Loose, torn, split, cracked,
damaged, hardened seals, or
holes in seals
2 Deterioration along bearing
areas on the pier caps and on
the columns
3 Accumulation of debris and
incompressible materials in
the seals
2. Cause
Problems Cause 1 Cause 2 Cause 3
Loose, torn, split, cracked,
damaged, hardened seals, or
holes in seals
Debris Poor installation Difficulties of
replacement/repair
Deterioration along bearing
areas on the pier caps and on
the columns
Deicing chemicals (e.g.,
salts)
Poor maintenance Poor or faulty drainage
details, Deicing
chemicals (e.g., salts),
Traffic-induced
movements and
vibration
Accumulation of debris and
incompressible materials in
the seals
Debris Poor maintenance Traffic density and axle
loading –live loads,
Traffic-induced
movements and
vibration
B4
3. Strength
Rank Item
1 Long performance history
2 Simple design and easy to specify
3 Versatile – could be used in
different sizes of bridge
4. Improvement
Rank Item
1 A larger curb opening that flush
themselves clear
2 Regular and frequent maintenance
3 Promoting the design of jointless
bridge decks
B5
I.A. JOINT (survey #1)
1. Problem
Rank Symptom
1 Cracked and spalled concrete, and rusted or
exposed reinforcement steel or structural
steel in the deck joints substrate
2 Loose, torn, split, cracked, damaged,
hardened seals, or holes in seals
3 Damage of epoxy fillers or adhesive
lubricants causing separation of the joint
material from the joint face
2. Cause
Problems Cause 1 Cause 2 Cause 3
Cracked and spalled
concrete, and rusted or
exposed reinforcement steel
or structural steel in the deck
joints substrate
Improper design of the
joint (e.g., Unarmored
joint edges)
Improper selection of materials
or using inferior quality of
materials in the joint (e.g., seals
are too hard or soft, sizes of seal
or wall thickness are not
adequate)
Traffic density and axle
loading –live loads,
Traffic-induced
movements and vibration
Loose, torn, split, cracked,
damaged, hardened seals, or
holes in seals
Age and material failure Lateral movement, such as
abutment tilting or embankment
movement, Abutment
settlement, and Approach slab
movement and settlement
Deicing chemicals (e.g.,
salts)
Damage of epoxy fillers or
adhesive lubricants causing
separation of the joint
material from the joint face
Poor installation Poor or faulty drainage details Simple wear and tear
B6
3. Strength
Rank Item
1 Simple design and easy to specify
2 Low construction cost
3 Easy to install
4. Improvement
Rank Item
1 Removing the damaged parts and installing new ones
2 Promoting the design of jointless bridge decks
3 Making notch deeper & filling with silicone (eliminate
neoprene)
B7
XJS JOINT (survey #1)
1. Problem
Rank Symptom
1 Loose, torn, split, cracked, damaged, hardened nosing
materials
2 Traffic comes into contact with silicone
3 Damage of epoxy fillers or adhesive lubricants causing
separation of the joint material from the joint face
2. Cause
Problems Cause 1 Cause 2 Cause 3
Loose, torn, split, cracked,
damaged, hardened nosing
materials
Improper design of the
joint (e.g., Unarmored
joint edges)
Improper selection of materials or using
inferior quality of materials in the joint
(e.g., seals are too hard or soft, sizes of
seal or wall thickness are not adequate)
Simple wear and tear
Improper selection of materials or using
inferior quality of materials in the joint
(e.g., seals are too hard or soft, sizes of
seal or wall thickness are not adequate)
Deteriorated bonding agents
Traffic comes into contact
with silicone
Poor installation None None
Damage of epoxy fillers or
adhesive lubricants causing
separation of the joint
material from the joint face
Poor installation Inadequate bond Improper selection of
joint type
B8
3. Strength
Rank Item
1 Simple design and easy to specify
2 Smooth ride
3 Few debris accumulated in the joint
4. Improvement
Rank Item
1 Use specialty contractors to install the joints
2 Removing the damaged parts and installing new ones
3 Making manufacturers or contractors responsible for the
installation and maintenance of the joints
B9
LDI JOINT (survey #1)
1. Problem
Rank Symptom
1 Loose, torn, split, cracked,
damaged, hardened seals, or
holes in seals (polymer
material)
2 Tracking and flowing of
polymer during hot weather
3 Loose, rusted, cracked,
missing, or damaged steel
plates
2. Cause
Problems Cause 1 Cause 2 Cause 3
Loose, torn, split, cracked,
damaged, hardened seals, or
holes in seals (polymer
material)
Unacceptable range of
movements and end
rotations of the deck
Temperature changes No testing of materials,
too much reliance on
material certifications
(type A,B, C, etc.)
Tracking and flowing of
polymer during hot weather
Unacceptable range of
movements and end
rotations of the deck
No testing of materials, too
much reliance on material
certifications (type A, B, C,
etc.)
Improper selection of
materials or using inferior
quality of materials in the
joint (e.g., seals are too
hard or soft, sizes of seal
or wall thickness are not
adequate)
Loose, rusted, cracked,
missing, or damaged steel
plates
Poor installation Unacceptable range of
movements and end rotations of
the deck
Inadequate site
preparation, Inadequate
bond
B10
3. Strength
Rank Item
1 Smooth ride
2 Few debris accumulated in the joint
3 Versatile – could be used in
different sizes of bridge
4. Improvement
Rank Item
1 Promoting the design of jointless bridge decks
2 Making manufacturers or contractors responsible for the
installation and maintenance of the joints
3 Using specialty contractors to install the joints
Estimated Joint Life (survey #1)
Joint Type S.S. B.S. I.A. XJS LDI
Estimated
Life (yr.)
11.9 11.706 8.728 5.19 3.502
APPENDIX C Questionnaire of the Second Survey
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INVESTIGATION OF BRIDGE DECK EXPANSION JOINTS Objective The deck expansion joints are among the smallest elements of a bridge structure. However, they could incur costs higher than anticipated because of frequent maintenance and repair problems. In order to get more insight into the field performance of the joints, this questionnaire is designed to quantify the problems and causes related to the bridge deck expansion joints. We invite your inputs and to tell us how to fix those problems. It is hoped that in this way better understanding of the performance of the joints could be obtained, and the results could serve as the future reference of the evaluation criteria for different types of joints.
Introduction There are three parts in this questionnaire. Part I is a simple investigation of your background. We like to know a little about you so we can see how different types of people feel about the issues.
Part II is the investigation of the problems, causes, merits, and improvements for each joint. We like you to point out what are the problems and causes associated with each type of joint, the advantages of using each type of joint, and better ways to improve the joints’ performance. In this questionnaire survey, we concentrate on the investigation of seven types of expansion joints. They are Compression Seal (B.S.), Strip Seal (S.S.), Poured Dow Corning Silicone (XJS), Jointless (I.A.) with the poured sealer and the neoprene seal, and Polymer Modified Asphalt joints (LDI and Pave Tech).
To facilitate your correspondence to the questions, we provide a separate set of sample answers for the problems each joint may have, the causes of the identified problems, the advantages of using the specific joint, and better ways to improve the performance of each joint. The simplified example drawings of the joints are attached to help you clarify what kinds of joints we are referring to.
Part III is the recommendation. We like you to select the three best joints on your opinion, to estimate the service life of each joint, and to put any comment you have about the joint and the questionnaire.
Since the list of choices in the questionnaire may not be inclusive, please write your own answers if you could not find them from sample answers. If you do not have experience with one of the types of the joints, simply leave it blank or just put a question mark.
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Part I: Background 1. How many years have you worked related to bridge inspection? ________years 2. How many years have you worked related to bridge inspection for (IDOT, INDOT,
KDOT, MDOT, ODOT) ________ years
3. What kind of position do you have? _______
a. Bridge engineer b. Bridge inspector c. Assistant Inspector d. Other (please specify)___________
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Part II: The Problems, Causes, Merits, and Improvements associated
with the Bridge Deck Expansion Joints There will be four sub-sections (a), (b), (c), and (d) for each joint. The section (a) is the investigation of the most severe problems of the joints; the section (b) is the investigation of the causes of the problems identified in (a); the section (c) is of the strengths; and the section (d) is of the improvements. The lists of possible problems, causes, strengths, and improvements are shown in the attached sample answers. Write your own answers if you could not find them from the list. Multiple choices of the answers are allowed in each blank. Please see the example on the next page. If you are not sure which type of joint we are referring to, please see the attached example drawings. (a) Problems Please select and rank the three most severe problems for each type of joint from the attached sample answers.
(b) Causes For each problem you select for each type of the joint in (a), please find three most possible causes from the attached sample answers. The most possible one is filled out first. (c) Strengths Please select three major strengths of each type of the joints from the attached sample answers. The most important one is filled out first. (d) Improvements For each type of the join, please find out three most possible improvements of its performance from the attached sample answers. The most important one is filled out first.
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EXAMPLE: B.S. JOINT (Compression Seal)
(a) Problems (see sample answers, pp. 1-2) The most severe problem: 5.1, 5.2 .
The second severe problem: 7.1, 7.2 .
The third severe problem: 1.1 .
(b) Causes (see sample answers, pp. 3-5) For the most severe problem: 1. 2.1 , 2. 6.3 , 3. 4.1 .
For the second severe problem: 1. 6.3 , 2. 7.2 , 3. 1.6 .
For the third severe problem: 1. 6.2 , 2. 2.2,2.3 , 3. 3.1,3.8 .
(c) Strength (see sample answers, pp. 6) 1. 12 , 2. 9 , 3. 16 . (d) Improvement (see sample answers, pp. 7) 1. 10 , 2. 5 , 3. 3 .
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C5
1. B.S. JOINT (Compression Seal)
(a) Problems The most severe problem: __________
The second severe problem: __________
The third severe problem: __________
(b) Causes For the most severe problem: 1.______, 2.______, 3.______
For the second severe problem: 1.______, 2.______, 3.______
For the third severe problem: 1.______, 2.______, 3.______
(c) Strength 1.________, 2.________, 3.________ (d) Improvement 1.________, 2.________, 3.________
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2. S.S. JOINT (Strip Seal) (a) Problems The most severe problem: __________
The second severe problem: __________
The third severe problem: __________
(b) Causes For the most severe problem: 1.______, 2.______, 3.______
For the second severe problem: 1.______, 2.______, 3.______
For the third severe problem: 1.______, 2.______, 3.______
(c) Strength 1.________, 2.________, 3.________ (d) Improvement 1.________, 2.________, 3.________
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3a. I.A. JOINT (Jointless with the Poured Sealer) (a) Problems The most severe problem: __________
The second severe problem: __________
The third severe problem: __________
(b) Causes For the most severe problem: 1.______, 2.______, 3.______
For the second severe problem: 1.______, 2.______, 3.______
For the third severe problem: 1.______, 2.______, 3.______
(c) Strength 1.________, 2.________, 3.________ (d) Improvement 1.________, 2.________, 3.________
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3b. I.A. JOINT (Jointless with the Neoprene Seal)
(a) Problems The most severe problem: __________
The second severe problem: __________
The third severe problem: __________
(b) Causes For the most severe problem: 1.______, 2.______, 3.______
For the second severe problem: 1.______, 2.______, 3.______
For the third severe problem: 1.______, 2.______, 3.______
(c) Strength 1.________, 2.________, 3.________ (d) Improvement 1.________, 2.________, 3.________
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4. POURED DOW CORNING SILICONE JOINT (XJS) (a) Problems The most severe problem: __________
The second severe problem: __________
The third severe problem: __________
(b) Causes For the most severe problem: 1.______, 2.______, 3.______
For the second severe problem: 1.______, 2.______, 3.______
For the third severe problem: 1.______, 2.______, 3.______
(c) Strength 1.________, 2.________, 3.________ (d) Improvement 1.________, 2.________, 3.________
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5a. LDI -POLYMER MODIFIED ASPHALT JOINT (a) Problems The most severe problem: __________
The second severe problem: __________
The third severe problem: __________
(b) Causes For the most severe problem: 1.______, 2.______, 3.______
For the second severe problem: 1.______, 2.______, 3.______
For the third severe problem: 1.______, 2.______, 3.______
(c) Strength 1.________, 2.________, 3.________ (d) Improvement 1.________, 2.________, 3.________
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C11
5b. PAVE TECH -POLYMER MODIFIED ASPHALT JOINT (a) Problems The most severe problem: __________
The second severe problem: __________
The third severe problem: __________
(b) Causes For the most severe problem: 1.______, 2.______, 3.______
For the second severe problem: 1.______, 2.______, 3.______
For the third severe problem: 1.______, 2.______, 3.______
(c) Strength 1.________, 2.________, 3.________ (d) Improvement 1.________, 2.________, 3.________
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C12
Part III: Recommendation
(a) Estimated Service Life
Based on your experience, how many years in average did each type of the joint last after it was installed? 1. B.S. JOINT: __________ years 2. S.S. JOINT: __________ years 3. I.A. (POURED SEALER) JOINT: __________ years 4. I.A. (NEOPRENE SEAL) JOINT: __________ years 5. POURED DOW SILICONE (XJS) JOINT: __________ years 6. LDI JOINT: __________ years 7. PAVE TECH JOINT: __________ years
(b) Based on your observation, please select the three best joints in terms of its overall performance and briefly explain the reason why you choose them (not limited to the joints listed in this survey).
1.__________________
Reason:
2.__________________
Reason:
3.__________________
Reason:
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C13
(c) Comment If you have any comment on each joint, please write it down here. ________________________________________________________________________
________________________________________________________________________
________________________________________________________________________
________________________________________________________________________
________________________________________________________________________
________________________________________________________________________
________________________________________________________________________
(d) Any suggestion on the design of the questionnaire?
________________________________________________________________________
________________________________________________________________________
________________________________________________________________________
________________________________________________________________________
________________________________________________________________________
________________________________________________________________________
________________________________________________________________________
This concludes the questionnaire; please review your responses and ensure you have answered all questions. Thank you very much for your participation.
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C14
SAMPLE ANSWERS (a) Problems 1. Damaged seals due to ______ 1.1 Loose 1.2 Torn 1.3 Split 1.4 Cracks 1.5 Hardened 1.6 Holes 1.7 Other (please specify)__________
2. Damage of adhesive lubricants causing separation of the joint material from the joint
face 3. Accumulation of debris and incompressible materials in the seals 4. ______ components of the joint are damaged 4.1 Steel plates 4.2 Anchorage 4.3 Holddown bars 4.4 Bolts 4.5 Welding 4.6 Aluminum plates 4.7 Other (please specify)__________
5. ______ concrete around the joint 5.1 Cracked concrete 5.2 Spalled concrete 5.3 Other (please specify)__________
6. Rusted steel components _____ in the deck joints substrate raise the deck that impacts
traffic and damages the ends of the deck 6.1 Reinforcement steel 6.2 Bearing elements 6.3 Top flanges of beams 6.4 Other (please specify)_________
7. Deterioration along ______ 7.1 Cap areas
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C15
7.2 Beam ends 7.3 Other (please specify)__________
8. Deterioration of ______ 8.1 Bearings 8.2 Abutments 8.3 Columns 8.4 Other (please specify)__________
9. Evidence of water leakage on ______ 9.1 The underside of the deck 9.2 At the curbline 9.3 At the bent cap 9.4 Other (please specify)__________
10. Evidence of noise during the passage of vehicles over the joint 11. Restriction on freedom of joint movement causing problems such as _____of the deck 11.1 Transverse movements 11.2 Horizontal movements 11.3 Other (please specify)__________
12. Evidence of ______of joints 12.1 Rotation 12.2 Tilting 12.3 Settlement 12.4 Other (please specify)__________
13. Poor ridebility 14. Inadequate skid resistance 15. Others (please specify) 15.1 _______________________________________________________
15.2 _______________________________________________________
15.3 _______________________________________________________
15.4 _______________________________________________________
15.5 _______________________________________________________
15.6 _______________________________________________________
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C16
(b) Causes 1. Natural Forces
1.1 Carbon dioxide 1.2 Dust 1.3 Ice freezing 1.4 Moisture 1.5 Ozone 1.6 Rain 1.7 Snow 1.8 Sun 1.9 Significant changes of temperatures between summer and winter 1.10 Ultraviolet rays
2. Traffic Vehicle
2.1 Traffic density and axle loading – live loads 2.2 Traffic-induced movements 2.3 Traffic-induced vibration 2.4 Snow plows 2.5 Trucks
3. Bridge structure
3.1 Abutment settlement 3.2 Approach slab movement and settlement 3.3 Camber growth 3.4 Displacement of bearings 3.5 Excessive shrinkage, creep, deflection, or rotation in deck slabs 3.6 Fatigue of the metal components 3.7 Failure of the fixings of other steel components 3.8 Inadequate anchorage 3.9 Inadequate bedding 3.10 Lateral movement, such as abutment tilting or embankment movement
4. Design
4.1 Improper mix preparation, cure, compaction, shrinkage ,or thickness of surfacing and hand mixed materials
4.2 Incorrect deck superelevation 4.3 Incorrect joint openings 4.4 Incorrect joint alignments 4.5 Incorrect position of bearing 4.6 Insufficient clearance between the top of the deck and the top of the joint materials 4.7 Improper selection of the joint type
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C17
4.8 Lack of detailed drawings for the installation of joints 4.9 Poor design and performance of bearings 4.10 Poor or faulty drainage details 4.11 Skewed bridge structures 4.12 Steel plates too thin 4.13 Unacceptable range of movements of the joint
5. Construction
5.1 Inadequate site preparation 5.2 Inappropriate temperature in which the joint was being installed 5.3 Joint seal not released sufficiently 5.4 Loose concrete adjacent to joint materials 5.5 Poor installation 5.6 Poor vertical alignment (The joint is not at the proper level or not constructed in
the same plane as the bridge deck) 5.7 Poor workmanship 5.8 Seal punctures during installation resulting in tears later 5.9 Seals not properly installed – not properly seated in extrusion
6. External Forces
6.1 Cement alkalis 6.2 Debris 6.3 Deicing chemicals (e.g. salts) 6.4 Detritus 6.5 Grit 6.6 Industrial pollutants 6.7 Petroleum derivatives 6.8 Simple wear and tear 6.9 Vegetation growth near the curbs
7. Material Failure
7.1 Failure of bonding agents 7.2 Improper selection of materials or using inferior quality of materials in the joint (
e.g., seals are too hard or soft, inadequate sizes of seal or wall thickness) 7.3 Seals being pushed up during hot weather conditions 7.4 The failure of the deck overlay adjacent to the joint
8. Others
8.1 Deteriorated bituminous materials 8.2 Difficulties of cleaning 8.3 Difficulties of replacement/repair 8.4 Limited access to bearing shelves for maintenance
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C18
8.5 Poor fabrication of joints 8.6 Poor inspection 8.7 Poor maintenance 8.8 Vandalism
9. Other causes not included in the list (please specify)
9.1 ___________________________________________
9.2 ___________________________________________
9.3 ___________________________________________
9.4 ___________________________________________
9.5 ___________________________________________
9.6 ___________________________________________
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C19
(c) Strength The following list shows possible strengths of the joint. 1. Allowing required movements 2. Durable and trouble free 3. Easy maintenance and repair 4. Easy to install 5. Eliminating time consuming and costly shop drawings 6. Excellent weathering properties 7. Few debris accumulated in the joint 8. Long performance history 9. Low construction cost 10. Rapid curing 11. Resilient filler 12. Simple design and easy to specify 13. Smooth ride 14. Strong mechanical property 15. Strong seal 16. Versatile – could be used in different sizes of bridge 17. Water tight 18. Others (please specify) 19.1 _________________________________________
19.2 _________________________________________
19.3 _________________________________________
19.4 _________________________________________
19.5 _________________________________________
19.6 _________________________________________
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C20
(d) Improvements The following list shows some possible improvements on the service life of the joints. 1. A larger curb opening that flush themselves clear 2. A non-corroding extrusion 3. Armoring - protection against live-load impact 4. Arranging surface slopes and gully positions 5. Better installation process 6. Detailed installation plans provided by the manufacturer or the designer 7. Improving joint drainage system 8. Making manufacturers or contractors responsible for the installation and maintenance
of the joints 9. Regular and frequent inspection 10. Regular and frequent maintenance 11. Repairing or modifying the joint openings 12. Selecting a correct type of joint 13. Strengthening the bonding between seals and the attached mateirals 14. Testing of materials 15. Tying approaching slabs to deck 16. Using rubber snowplow blades in the snow removal equipment 17. Using specialty contractors to install the joints 18. Others (please specify)
19.1 _________________________________________
19.2 _________________________________________
19.3 _________________________________________
19.4 _________________________________________
19.5 _________________________________________
19.6 _________________________________________
APPENDIX D Result of the Second Survey
D1
B.S. JOINT (survey #2)
1. Problem
Level Symptom
The most severe Loose seal
The second severe Damaged adhesive lubricants
The third severe Spalled concrete
2. Cause
Problems Cause 1 Cause 2 Cause 3
Loose seal Failure of bonding
agents
Incorrect joint openings Inadequate anchorage
Damaged adhesive
lubricants
Failure of bonding
agents
Inadequate site
preparation
1. Poor installation
2. Trucks
Spalled concrete Traffic density and axle
loading
Failure of bonding
agents
Simple wear and tear
3. Strength
1 Allowing required movements
2 Simple design and easy to specify
3 Low construction cost
4. Improvement
1 Strengthening the bonding between seals and the
attached materials
2 Regular and frequent maintenance
3 Making manufacturers or contractors responsible
for the installation and maintenance of the joints
D2
S.S. JOINT (survey #2)
1. Problem
Level Symptom
The most severe Torn seal
The second severe Accumulation of debris
The third severe Split seal
2. Causes
Problems Cause 1 Cause 2 Cause 3
Torn seal Debris Snow plow Seal punctures during
installation resulting in
tears later
Accumulation of debris Debris Grit Poor maintenance
Split seal Debris Seal punctures during
installation resulting in
tears later
Simple wear and tear
3. Strength
1 Allowing required movements
2 Easy to install
3 Durable and trouble free
4. Improvement
1 Regular and frequent maintenance
2 A larger curb opening that flush themselves clear
3 Better installation process
D3
I.A. JOINT (Poured Sealer) (survey #2)
1. Problem
Level Symptom
The most severe Hardened seal
The second severe Spalled concrete
The third severe Cracked concrete
2. Causes
Problems Cause 1 Cause 2 Cause 3
Hardened seal Ultraviolet rays Sun Simple wear and tear
Spalled concrete Traffic density and axle
loading
Seals being pushed up
during hot weather
conditions
Snow plows
Cracked concrete 1. Temperatures
change between
summer and winter
2. Traffic density and
axle loading
1. Moisture
2. Snow plows
N/A
3. Strength
1 Easy to install
2 Low construction cost
3 Durable and trouble free
4. Improvement
1 Regular and frequent maintenance
2 Better installation process
3 Strengthening the bonding between seals and the
attached materials
D4
I.A. JOINT (Neoprene Seal) (survey #2)
1. Problem
Level Symptom
The most severe Spalled concrete
The second severe Loose seal
The third severe Cracked concrete
2. Causes
Problems Cause 1 Cause 2 Cause 3
Spalled concrete Traffic density and axle
loading
Seals being pushed up
during hot weather
conditions
Poor installation
Loose seal Poor installation Temperatures change
between summer and
winter
Traffic-induced
movements
Cracked concrete 1. Traffic density and
axle loading
2. Failure of bonding
agents
Seals being pushed up
during hot weather
conditions
N/A
3. Strength
1 Easy to install
2 Long performance history
3 Allowing required movements
4. Improvement
1 Strengthening the bonding between seals and the
attached materials
2 Very little use
3 Better installation process
D5
XJS JOINT (survey #2)
1. Problem
Level Symptom
The most severe Loose seal
The second severe Cracked seal
The third severe Holes in seal
2. Causes
Problems Cause 1 Cause 2 Cause 3
Loose seal Poor workmanship Failure of bonding
agents
Poor installation
Cracked seal Poor installation Poor workmanship Inadequate site
preparation
Holes in seal Poor installation Poor workmanship Inadequate site
preparation
3. Strength
1 Easy to install
2 Easy maintenance and repair
3 Water tight
4. Improvement
1 Better installation process
2 Strengthening the bonding between seals and the
attached materials
3 Detailed installation plans provided by the
manufacturer or the designer
D6
LDI JOINT (survey #2)
1. Problem
Level Symptom
The most severe Cracked seal
The second severe Holes in seal
The third severe Split seal
2. Causes
Problems Cause 1 Cause 2 Cause 3
Cracked seal Poor installation Improper selection of
materials or using
inferior quality of
materials in the joint
1. Incorrect joint
openings
2. Inadequate bedding
Holes in seal Traffic density and axle
loading
Snow plows Seals being pushed up
during hot weather
conditions
Split seal Unacceptable range of
movements of the joint
Snow plows Poor installation
3. Strength
1 Allowing required movements
2 Easy to install
3 Few debris accumulated in the joint
4. Improvement
1 Better installation process
2 Very little use
3 Using specialty contractors to install the joints
D7
PAVE TECH JOINT (survey #2)
1. Problem
Level Symptom
The most severe Polymer too soft (rutting)
The second severe Cracked seal
The third severe Holes in seal
2. Causes
Problems Cause 1 Cause 2 Cause 3
Polymer too soft
(rutting)
Traffic density and axle
loading
Improper selection of
materials or using
inferior quality of
materials in the joint
Incorrect join openings
Cracked seal Poor installation 1. Snow plows
2. Poor workmanship
N/A
Holes in seal Traffic density and axle
loading
Snow plows Seals being pushed up
during hot weather
conditions
3. Strength
1 Allowing required movements
2 Easy to install
3 Excellent weathering properties
4. Improvement
1 Selecting a correct type of joint
2 Very little use
3 Using specialty contractors to install the joints
D8
Estimated Joint Life (survey #2)
Joint Type S.S. B.S. I.A.
(Poured sealer)
I.A.
(Neoprene
seal)
PaveTech LDI XJS
Estimated Life
(yr.) 10.92 10.3 9.79 7.33 5.82 5.74 5.56
APPENDIX E Numerical Example of Survey Data Analysis
B.S. Problems N o . 1 2 3 4 5 6 7 8 9 1 0 1 1 1 2 1 3 1 4 1 5 1 6 1 7 1 8 T o l. N u m . A v g 1 A v g 2
Y r. 2 0 6 5 .5 2 2 2 8 5 3 .5 1 4 4 0 .2 5 1 1 6 4 2 7 1 5 3 .2 5 1 1 6 6 .5P ro b .
1 2 3 1 3 1 2 1 3 2 2 1 2 2 2 5 1 3 1 .9 2 3 0 .0 2 3 0 32 0 6 5 .5 3 .5 1 4 4 0 .2 5 1 1 6 4 5 3 .2 5 1 8 3 .5
2 3 2 1 3 3 3 2 1 7 7 2 .4 2 9 0 .0 5 1 1 32 0 5 1 4 0 .2 5 4 1 3 .2 5 4 7 .5
3 2 1 4 1 2 3 1 2 1 6 8 2 0 .0 6 1 5 41 4 4 0 .2 5 4 1 5 3 .2 5 1 3 2 .5
4 3 3 2 2 1 0 4 2 .5 0 .1 1 2 3 61 4 4 3 .2 5 1 2 2 .2 5
5 1 1 1 1 1 3 2 1 2 1 1 2 1 7 1 2 1 .4 1 7 0 .0 0 9 5 72 0 6 2 2 2 8 5 3 .5 1 4 0 .2 5 1 1 6 2 7 1 3 .2 5 1 1 4 8
6 2 2 1 2 3 1 1 2 1 4 8 1 .7 5 0 .0 2 4 8 25 .5 3 .5 1 4 0 .2 5 1 6 2 7 3 .2 5 1 7 0 .5
7 2 3 5 2 2 .5 0 .1 4 4 9 31 4 3 .2 5 1 7 .2 5
8 3 3 6 2 3 0 .1 7 3 9 11 4 3 .2 5 1 7 .2 5
9 3 3 6 2 3 0 .1 7 3 9 11 4 3 .2 5 1 7 .2 5
1 0 3 3 6 2 3 0 .1 7 3 9 11 4 3 .2 5 1 7 .2 5
1 1 2 3 2 2 1 1 1 1 3 2 1 2 2 1 1 2 1 .7 5 0 .0 1 2 7 56 5 .5 2 2 2 8 5 3 .5 1 4 1 1 6 2 7 5 3 .2 5 1 1 3 7 .2 5
1 2 3 3 3 2 3 1 4 5 2 .8 0 .0 3 8 7 52 2 2 8 5 1 4 3 .2 5 7 2 .2 5
1 3 3 3 6 2 3 0 .0 8 2 7 62 8 5 3 .2 5 3 6 .2 5
1 4 2 2 1 2 0 .0 7 1 4 32 8 2 8
1 5 1 1 1 1 0 .25 5
For each problem:1. 1 is assigned to the most severe problem, 2 is to the second, and 3 is to the third severe problem. 2. The sum of numbers assigned to the problem is divided by the number of people who selected it to obtain the value of Avg1.3. The value of Avg1 is divided by the total numbers of years of experiences of the people who selected this problem to obtain the value of Avg2.4. Finally the problem with the smallest value of Avg2 is the most severe problem, the one with the second smallest value is the second most severe problem, and so on.
B.S. Causes
No. 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18Cause 1 8.1 4.15 4.12 2.1 2.1 2.1 6.2 2.1 7.3 5.4 6.2 1, 6.2, 2.2, 2.3 6.8 5.1,5.4 4.1 6.8,5.9 6.2 7.1Cause 2 2 5.4 6.2 4.1 4.1 1.1,1.6,1.7 1.1 6.1 1.2 1.1 3.3, 3.4, 3.5 7.1 6.2 7.1 7.1 6.1 5.1Cause 3 6.1 6.8 6.1 4.8 4.8 6.2 8.1 6.2 4.1 6.1 3.3, 3.4, 3.5 6.2 5.1 7.1 6.8 6.7
Prob. 1 8.1 8.1 2.1 6.2 1.1 2.2,2.3 4.1 5.1Yr. of Exp. 20 6 55 44.25 1 16 1 1
Num. 1 1 3 3 1 1 1 1Total 20 6 165 132.75 1 16 1 1Rank 3 1 2
Prob. 2 5.4 6.1 4.1 1.6,1.7 1.1 2.1 6.2 7.1 5.1Yr. of Exp. 6 5.5 22 5 8.5 14 47.25 5 1Num. 1 1 1 1 2 1 4 1 1Total 6 5.5 22 5 17 14 189 5 1Rank 2 3 1
Prob. 3 2.2,2.3 6.8 4.12 8.1 2.1 1.2 5.4 6.1 3.3, 3.4, 3.5 7.1 5.9
Yr. of Exp. 20 11 5.5 3.5 14 4 0.25 4.25 16 4 5Num. 1 2 1 1 1 1 1 2 1 1 1Total 20 22 5.5 3.5 14 4 0.25 8.5 16 4 5Rank 2 1 3
1. The three most severe problems are obtained from the result of the previous page.2. For each cause selected for the problem, the total number of the years of experiences of people who selected the cause are multiplied by the number of people to get the value of Total. 3. The cause which has the largest value of Total is the most possible cause for the problem, the cause with the second largest value is the second most possible cause, and so on.
B.S. Advantages
N o . 1 2 3 4 5 6 7 8 9 1 0 1 1 1 2 1 3 1 4 1 5 1 6 1 7 1 8 T o l. N u m . A v g 1 A v g 2 R a n kA d v .1 a a g a m m b c a a f j a q a aA d v .2 g m b m a a c a p g n g q m bA d v .3 d c d b b b m g h i q p c
a 1 1 1 2 2 2 1 1 1 1 1 1 4 1 1 1 .2 7 3 0 .0 0 9 4 6 12 0 6 2 2 2 8 5 1 4 4 0 .2 5 2 7 5 3 .2 5 1 3 4 .5
b 2 3 3 3 1 2 1 4 6 2 .3 3 3 0 .0 3 4 75 .5 2 2 2 8 5 3 .5 3 .2 5 6 7 .2 5
c 3 2 1 3 9 4 2 .2 5 0 .0 8 4 1 16 3 .5 1 4 3 .2 5 2 6 .7 5
d 3 3 6 2 3 0 .1 1 7 6 52 0 5 .5 2 5 .5
e
f 1 1 1 1 0 .0 6 2 51 6 1 6
g 2 1 3 2 2 1 0 5 2 0 .0 2 9 2 32 0 5 .5 1 6 2 7 6 8 .5
h 3 3 1 3 0 .1 8 7 51 6 1 6
i 3 3 1 3 0 .1 1 1 1 12 7 2 7
j 1 1 1 1 0 .2 54 4
m 2 2 1 1 3 2 1 1 6 1 .8 3 3 0 .0 2 6 3 8 26 2 2 2 8 5 3 .5 5 6 9 .5
n 2 2 1 2 0 .54 4
o
p 2 3 5 2 2 .5 0 .2 7 7 7 84 5 9
q 2 2 1 2 21 1
2. The method of obtaining the ranking is the same as that for joint problems.3. No one selected k and l and they are deleted to save the space of the page.
1. 1 is assigned to the most important advantage, 2 is assigned to the second most important advantage, and 3 is to the third most important advantage.
B.S. Improvements
Im pt2 14 6 11 181 6 3 1 6 4 1 4 7 15,16 2 15
Im pt3 1 7 6 182 11 4 10 7 7 1 11 4 7
1 3 2 1 2 3 1 12 6 2 0.03265 220 14 4 16 4 3.25 61.25
2 1 2 3 2 1.5 2 0.0779216 3.25 19.25
3 2 1 1 4 3 1.333 0.03756 33.5 27 5 35.5
4 3 2 2 3 10 4 2.5 0.1162814 0.25 4 3.25 21.5
6 2 3 2 2 9 4 2.25 0.109766 5.5 5 4 20.5
7 3 1 3 3 2 3 15 6 2.5 0.046516 3.5 0.25 16 27 1 53.75
9 1 1 1 1 1 0.181825.5 5.5
10 3 3 1 3 0.754 4
11 1 1 2 1 1 1 3 3 13 8 1.625 3 0.01711 120 6 5.5 22 28 5 3.5 5 95
14 2 2 1 2 0.120 20
15 2 2 4 2 2 0.333335 1 6
16 1 1 1 2 1 6 5 1.2 0.0494814 0.25 4 5 1 24.25
181 2 2 1 2 0.0714328 28
182 3 3 1 3 0.1071428 28
1. 1 is assigned to the most important improvement, 2 is assigned to the second most important, and 3 is to the third most important improvement.2. The method of obtaining the ranking is the same as that for joint problems.3. 181 and 182 are the improvements suggested by inspectors who filled out the questionnaire..4. No one selected the improvement 5, 8, 12, 13, and 17, and they are deleted to save the space of the page.
Recommended Types of Joints
No. 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23Yr. 5 22 8 5 15 2 15 6 20 25 3 20 5 17 3 8 25 5 9 8 18 17 3B.S. 2 2 2 2 1 1 3 2 2 2 1 1 1 1 2 3S.S. 1 3 2 3 1 2 3 1 2 1 1
I.A.(a) 1 1 1 2 1I.A.(b) 2 1 1 2XJS 1 1 1 2 3 1 3 2 2LDI 3 1PT 3 3 3 2 3 2
No. 24 25 26 27 28 29 30 31 32 33 Tol Sum Avg Rank1 Wsum Wqty Wavg Rank2Yr. 4 6 1 5 20 5.5 6 11 17 23B.S. 2 3 3 19 36 1.8947 5 422 230 0.0966 1S.S. 1 1 1 1 1 16 25 1.5625 1 347.5 205.5 0.1057 2
I.A.(a) 1 2 2 3 2 10 16 1.6 2 143 87.5 0.1634 4I.A.(b) 2 2 6 10 1.6667 3 70 49 0.2381 5XJS 1 3 3 2 2 14 27 1.9286 6 269 138 0.1392 3LDI 1 3 5 1.6667 3 40 36 0.3704 7PT 1 7 17 2.4286 7 198 84 0.3367 6
1. The type of joint that is chosen as the best one is assigned as 1, the second best is assigned as 2, and the third one is assigned as 3.2. The value of Avg is obtained by dividing the total numbers given to a type of joint by the number of people who select it.3. The Wsum and Wqty are obtained by including the year of experience of each person. 4. The Wavg is obtained by dividing the Wsum by the value of Wqty for each type of joint.
Estimated Life of Joints
No. 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 Sub totalYr. 20 7-10 15 5 8 0-4 0 20 10 0 15 15 15 0 0.5 6 10-15 3-8
Avg. 20 8.5 15 5 8 2 0 20 10 0 15 15 15 0 0.5 6 12.5 5.5 158
Yr. 20 6 5.5 22 28 5 0 14 4 0 1 16 4 0 1 5 3.25 1 135.75
Sum 400 51 82.5 110 224 10 0 280 40 0 15 240 60 0 0.5 30 40.6 5.5 1589.125
11.70626
1. Sum = Year x Avg.2. Weighted average = Total of sum / Total of year
Weighted Average
Example Data Analysis of Overall Problem Ranking
1. Each alphabet represents a symptom of the joint problem listed in the questionnaire.
S y m p t o m S c o r e R a n k i n g S y m p t o m S c o r e R a n k i n g S y m p t o m S c o r e R a n k i n ga 0 . 0 2 3 3 a 0 . 0 1 1 1 a 0 . 0 2 4 2b 0 . 0 5 1 6 b 0 . 1 1 1 1 0 a a 0 . 1 1 1 1 1c 0 . 0 6 2 7 c 0 . 0 3 7 3 b 0 . 0 2 8 3d 0 . 0 1 0 1 d 0 . 0 6 8 6 d 0 . 0 1 3 1e 0 . 0 2 5 4 e 0 . 0 4 4 4 e 0 . 0 5 2 6f 0 . 1 4 5 1 1 f 0 . 1 4 3 1 2 f 0 . 1 1 0 1 0g 0 . 1 7 4 1 2 g 0 . 2 1 4 1 6 g 0 . 0 8 1 9h 0 . 1 7 4 1 2 h 0 . 0 8 8 9 h 0 . 0 5 9 8i 0 . 1 7 4 1 2 i 0 . 1 5 8 1 3 i 0 . 1 7 4 1 2j 0 . 0 1 3 2 j 0 . 0 2 6 2 j 0 . 0 3 6 4k 0 . 0 3 9 5 k 0 . 1 7 5 1 5 k 0 . 0 5 2 7l 0 . 0 8 3 9 l 0 . 2 1 4 1 6 l 0 . 1 7 4 1 2r 0 . 1 1 2 1 0 m 0 . 1 3 3 1 1 r 0 . 0 5 1 5w 0 . 0 7 1 8 s 0 . 1 6 7 1 4x 0 . 2 0 0 1 5 t 0 . 0 6 3 5
y 0 . 0 7 1 7z 0 . 0 7 4 8
S y m p t o m S c o r e R a n k i n g S y m p t o m S c o r e R a n k i n ga 0 . 0 3 8 4 a 0 . 0 1 0 1
a b 1 0 . 0 0 0 1 3 a g 0 . 1 8 2 1 4a c 0 . 0 4 5 5 a h 0 . 0 3 6 4q 0 . 0 3 6 2 a i 0 . 2 0 0 1 5
a d 0 . 2 0 0 1 1 a j 0 . 2 8 6 1 8a e 0 . 2 8 6 1 2 a k 0 . 2 8 6 1 8a f 0 . 0 7 1 8 a l 0 . 2 8 6 1 8b 0 . 0 3 6 3 b 0 . 0 3 7 5c 0 . 0 4 8 6 d 0 . 1 2 3 1 1d 1 0 . 0 0 0 1 3 e 0 . 0 6 0 6e 0 . 1 8 2 1 0 f 0 . 0 8 3 8f 1 0 . 0 0 0 1 3 g 0 . 1 4 3 1 3g 1 0 . 0 0 0 1 3 h 0 . 2 1 4 1 7h 1 0 . 0 0 0 1 3 i 0 . 1 0 0 1 0i 1 0 . 0 0 0 1 3 j 0 . 0 6 9 7j 0 . 0 5 0 7 k 0 . 0 8 6 9k 1 0 . 0 0 0 1 3 l 0 . 1 2 8 1 2l 1 0 . 0 0 0 1 3 p 0 . 0 2 5 2n 0 . 0 2 8 1 s 0 . 2 0 0 1 5o 0 . 1 0 5 9 v 0 . 0 3 3 3u 1 0 . 0 0 0 1 3
B . S . S . S . I . A .
X J S L D I
Example Data Analysis of Overall Problem Ranking (Cont.)
Symptom B.S. S.S. I.A. XJS LDI Total Rankinga 3 1 2 4 1 11 1j 2 2 4 7 7 22 2
b 6 10 3 3 5 27 3e 4 4 6 10 6 30 4d 1 6 1 13 11 32 5k 5 15 7 13 9 49 6c 7 3 14 6 21 51 7f 11 12 10 13 8 54 8h 12 9 8 13 17 59 9i 12 13 12 13 10 60 10l 9 16 12 13 12 62 11g 12 16 9 13 13 63 12n 16 18 14 1 21 70 13q 16 18 14 2 21 71 14p 16 18 14 22 2 72 15v 16 18 14 22 3 73 16
ac 16 18 14 5 21 74 17ah 16 18 14 22 4 74 17r 10 18 5 22 21 76 19af 16 18 14 8 21 77 20o 16 18 14 9 21 78 21t 16 5 14 22 21 78 21
ad 16 18 14 11 21 80 23y 16 7 14 22 21 80 23
ae 16 18 14 12 21 81 25s 16 14 14 22 15 81 25z 16 8 14 22 21 81 25
ab 16 18 14 13 21 82 28u 16 18 14 13 21 82 28w 8 18 14 22 21 83 30ag 16 18 14 22 14 84 31m 16 11 14 22 21 84 31ai 16 18 14 22 15 85 33aa 16 18 11 22 21 88 34aj 16 18 14 22 18 88 34ak 16 18 14 22 18 88 34al 16 18 14 22 18 88 34x 15 18 14 22 21 90 38
Example Data Analysis of Follow-up Survey (Difficulty of Maintenance)
1. Each alphabet represents a symptom of the joint problem listed in the questionnaire.
1 2 3 4 5 6 7 Total Weighted Total Ranking
District Vincennes Crawfordsville La Porte Greenfield Central Office Seymour Fort WayneYear of
Exp. 6 2 20 30 20 17 28 123
Weight 0.05 0.02 0.16 0.24 0.16 0.14 0.23 1.00m 6 1 1 2 9 4 7 30 4.57 1d 2 3 9 1 2 1 11 29 4.82 2a 1 5 13 6 1 5 4 35 5.47 3i 8 8 7 9 6 3 2 43 5.70 4h 13 9 4 8 7 2 5 48 5.93 5b 3 4 12 10 3 6 3 41 6.60 6n 10 7 2 7 8 7 8 49 6.72 7e 5 17 14 12 15 9 1 73 9.63 8k 14 11 6 3 13 14 14 75 9.80 9p 16 12 16 5 10 11 9 79 9.99 10g 7 10 10 15 4 10 10 66 10.10 11j 9 15 5 14 14 16 6 79 10.76 12o 11 6 3 17 12 8 15 72 11.74 13c 4 2 8 16 5 15 17 67 12.19 14l 15 14 15 4 16 13 16 93 12.41 15q 17 13 17 11 11 12 13 94 12.89 16f 12 16 11 13 17 17 12 98 13.65 17
APPENDIX F Questionnaire and Result of the Follow-up Survey
11/2/00
F1
Questionnaire for Ranking of Joint Problems 1. How many years have you worked as an inspector? ________years 2. How many years have you worked as an inspector for INDOT? ________ years 3. What kind of position do you have? _______
a. Bridge Engineer b. Inspector c. Assistant Inspector d. Others (specify)__________
4. Which district are you in? ________
a. Crawfordsville b. Fort Wayne c. Greenfield d. La Porte e. Seymour f. Vincennes
The following pages list possible problems for the B.S. joint, S.S. joint, I.A. joint, Poured
Dow silicone (XJS) joint, and Polymer Modified Asphalt joint. There are 17 items in
total and please rank these problems using the number 1 to 17 according to its severity. 1
represents the most severe problem, 2 is the next, …, and 17 represents the least severe
problem.
11/2/00
F2
Riding Quality
! Which problem contributes most to the poor riding quality of joints?
a) Loose, torn, split, cracked, damaged, hardened seals, or holes in seals
b) Damage of epoxy fillers or adhesive lubricants causing separation of the
joint material from the joint face c) Accumulation of debris and incompressible materials in the seals
d) Cracked and spalled concrete, and rusted or exposed reinforcement steel or
structural steel in the deck joints substrate e) Evidence of water leakage on the underside of the deck or at the curbline f) Evidence of noise during the passage of vehicles over the joint
g) Restriction on freedom of joint movement causing problems such as
transverse movements of the deck h) Evidence of rotation, tilting, or settlement of joints i) Incorrect joint opening and alignment j) Deterioration along bearing areas on the pier caps and on the columns k) Poor ridebility l) Inadequate skid resistance
m) Loose, rusted, cracked, missing, or damaged steel plates, shapes, anchorage,
bolts, nuts, holddown bars, and other metal components n) Loose, torn, split, cracked, damaged, or hardened nosing materials o) Backer rods fall off p) Tracking and flowing of polymer during hot weather q) Traffic comes into contact with silicone
11/2/00
F3
Water Leakage ! Which problem contributes most to the water leakage of joints?
a) Loose, torn, split, cracked, damaged, hardened seals, or holes in seals
b) Damage of epoxy fillers or adhesive lubricants causing separation of the
joint material from the joint face c) Accumulation of debris and incompressible materials in the seals
d) Cracked and spalled concrete, and rusted or exposed reinforcement steel or
structural steel in the deck joints substrate e) Evidence of water leakage on the underside of the deck or at the curbline f) Evidence of noise during the passage of vehicles over the joint
g) Restriction on freedom of joint movement causing problems such as
transverse movements of the deck h) Evidence of rotation, tilting, or settlement of joints i) Incorrect joint opening and alignment j) Deterioration along bearing areas on the pier caps and on the columns k) Poor ridebility l) Inadequate skid resistance
m) Loose, rusted, cracked, missing, or damaged steel plates, shapes, anchorage,
bolts, nuts, holddown bars, and other metal components n) Loose, torn, split, cracked, damaged, or hardened nosing materials o) Backer rods fall off p) Tracking and flowing of polymer during hot weather q) Traffic comes into contact with silicone
11/2/00
F4
Noise ! Which problem contributes most to the noise of joints?
a) Loose, torn, split, cracked, damaged, hardened seals, or holes in seals
b) Damage of epoxy fillers or adhesive lubricants causing separation of the
joint material from the joint face c) Accumulation of debris and incompressible materials in the seals
d) Cracked and spalled concrete, and rusted or exposed reinforcement steel or
structural steel in the deck joints substrate e) Evidence of water leakage on the underside of the deck or at the curbline f) Evidence of noise during the passage of vehicles over the joint
g) Restriction on freedom of joint movement causing problems such as
transverse movements of the deck h) Evidence of rotation, tilting, or settlement of joints i) Incorrect joint opening and alignment j) Deterioration along bearing areas on the pier caps and on the columns k) Poor ridebility l) Inadequate skid resistance
m) Loose, rusted, cracked, missing, or damaged steel plates, shapes, anchorage,
bolts, nuts, holddown bars, and other metal components n) Loose, torn, split, cracked, damaged, or hardened nosing materials o) Backer rods fall off p) Tracking and flowing of polymer during hot weather q) Traffic comes into contact with silicone
11/2/00
F5
Difficulty of Maintenance ! Which problem makes the joint most difficult to maintain?
a) Loose, torn, split, cracked, damaged, hardened seals, or holes in seals
b) Damage of epoxy fillers or adhesive lubricants causing separation of the
joint material from the joint face c) Accumulation of debris and incompressible materials in the seals
d) Cracked and spalled concrete, and rusted or exposed reinforcement steel or
structural steel in the deck joints substrate e) Evidence of water leakage on the underside of the deck or at the curbline f) Evidence of noise during the passage of vehicles over the joint
g) Restriction on freedom of joint movement causing problems such as
transverse movements of the deck h) Evidence of rotation, tilting, or settlement of joints i) Incorrect joint opening and alignment j) Deterioration along bearing areas on the pier caps and on the columns k) Poor ridebility l) Inadequate skid resistance
m) Loose, rusted, cracked, missing, or damaged steel plates, shapes, anchorage,
bolts, nuts, holddown bars, and other metal components n) Loose, torn, split, cracked, damaged, or hardened nosing materials o) Backer rods fall off p) Tracking and flowing of polymer during hot weather q) Traffic comes into contact with silicone
F6
Riding Quality
Ranking Item Symptom
1 d Cracked and spalled concrete, and rusted or exposed reinforcement steel or structural steel in the deck joints substrate
2 m Loose, rusted, cracked, missing, or damaged steel plates, shapes, anchorage, bolts, nuts, holddown bars, and other metal components
3 h Evidence of rotation, tilting, or settlement of joints
4 i Incorrect joint opening and alignment
5 n Loose, torn, split, cracked, damaged, or hardened nosing materials
6 p Tracking and flowing of polymer during hot weather
7 j Deterioration along bearing areas on the pier caps and on the columns
8 c Accumulation of debris and incompressible materials in the seals
9 b Damage of epoxy fillers or adhesive lubricants causing separation of the joint material from the joint face
10 a Loose, torn, split, cracked, damaged, hardened seals, or holes in seals
11 g Restriction on freedom of joint movement causing problems such as transverse movements of the deck
12 f Evidence or noise during the passage of vehicles over the joint
13 q Traffic comes into contact with silicone
14 o Backer rods fall off 15 e Evidence of water leakage on the underside of the deck or at the curbline 16 l Inadequate skid resistance
F7
Water Leakage
Ranking Item Symptom
1 a Loose, torn, split, cracked, damaged, hardened seals, or holes in seals
2 b Damage of epoxy fillers or adhesive lubricants causing separation of the joint material from the joint face
3 d Cracked and spalled concrete, and rusted or exposed reinforcement steel or structural steel in the deck joints substrate
4 n Loose, torn, split, cracked, damaged, or hardened nosing materials
5 c Accumulation of debris and incompressible materials in the seals
6 m Loose, rusted, cracked, missing, or damaged steel plates, shapes, anchorage, bolts, nuts, holddown bars, and other metal components
7 i Incorrect joint opening and alignment
8 q Traffic comes into contact with silicone
9 h Evidence of rotation, tilting, or settlement of joints
10 p Tracking and flowing of polymer during hot weather
11 g Restriction on freedom of joint movement causing problems such as transverse movements of the deck
12 j Deterioration along bearing areas on the pier caps and on the columns
13 o Backer rods fall off
14 f Evidence or noise during the passage of vehicles over the joint 15 k Poor ridebility
16 l Inadequate skid resistance
F8
Noise
Ranking Item Symptom
1 m Loose, rusted, cracked, missing, or damaged steel plates, shapes, anchorage, bolts, nuts, holddown bars, and other metal components
2 d Cracked and spalled concrete, and rusted or exposed reinforcement steel or structural steel in the deck joints substrate
3 i Incorrect joint opening and alignment
4 h Evidence of rotation, tilting, or settlement of joints
5 k Poor ridebility
6 n Loose, torn, split, cracked, damaged, or hardened nosing materials
7 p Tracking and flowing of polymer during hot weather
8 c Accumulation of debris and incompressible materials in the seals
9 a Loose, torn, split, cracked, damaged, hardened seals, or holes in seals
10 b Damage of epoxy fillers or adhesive lubricants causing separation of the joint material from the joint face
11 g Restriction on freedom of joint movement causing problems such as transverse movements of the deck
12 j Deterioration along bearing areas on the pier caps and on the columns
13 o Backer rods fall off
14 q Traffic comes into contact with silicone
15 e Evidence of water leakage on the underside of the deck or at the curbline
16 l Inadequate skid resistance
F9
Difficulty of Maintenance
Ranking Item Symptom
1 m Loose, rusted, cracked, missing, or damaged steel plates, shapes, anchorage, bolts, nuts, holddown bars, and other metal components
2 d Cracked and spalled concrete, and rusted or exposed reinforcement steel or structural steel in the deck joints substrate
3 a Loose, torn, split, cracked, damaged, hardened seals, or holes in seals
4 i Incorrect joint opening and alignment
5 h Evidence of rotation, tilting, or settlement of joints
6 b Damage of epoxy fillers or adhesive lubricants causing separation of the joint material from the joint face
7 n Loose, torn, split, cracked, damaged, or hardened nosing materials
8 e Evidence of water leakage on the underside of the deck or at the curbline 9 k Poor ridebility
10 p Tracking and flowing of polymer during hot weather
11 g Restriction on freedom of joint movement causing problems such as transverse movements of the deck
12 j Deterioration along bearing areas on the pier caps and on the columns 13 o Backer rods fall off 14 c Accumulation of debris and incompressible materials in the seals 15 l Inadequate skid resistance 16 q Traffic comes into contact with silicone 17 f Evidence or noise during the passage of vehicles over the joint
F10
Ranking of Problem (Follow-up Survey)
B.S. Item Symptom Riding Quality Water Leakage Noise Maintenance
d Cracked and spalled concrete, and rusted or exposed reinforcement steel or structural steel in the deck joints substrate 3 4 2 1
j Deterioration along bearing areas on the pier caps and on the columns 10 12 14 13
a Loose, torn, split, cracked, damaged, hardened seals 12 2 9 3
Total 25 18 25 17
S.S. Item Symptom Riding Quality Water Leakage Noise Maintenance
a Loose, torn, split, cracked, damaged, hardened seals, or holes in seals 12 2 9 3
j Deterioration along bearing areas on the pier caps and on the columns 10 12 14 13
c Accumulation of debris and incompressible materials in the seals 11 6 10 9
Total 33 20 33 25
I.A. Item Symptom Riding Quality Water Leakage Noise Maintenance
d Cracked and spalled concrete, and rusted or exposed reinforcement steel or structural steel in the deck joints substrate 3 4 2 1
a Loose, torn, split, cracked, damaged, hardened seals, or holes in seals 12 2 9 3
b Damage of epoxy fillers or adhesive lubricants causing separation of the joint material from the joint face 8 3 12 8
Total 23 9 23 12
F11
XJS
Item Symptom Riding Quality Water Leakage Noise Maintenance
n Loose, torn, split, cracked, damaged, hardened nosing materials 5 8 7 4
q Traffic comes into contact with silicone 15 10 16 16
b Damage of epoxy fillers or adhesive lubricants causing separation of the joint material from the joint face 8 3 12 8
Total 28 21 35 28
LDI
Item Symptom Riding Quality Water Leakage Noise Maintenance
a Loose, torn, split, cracked, damaged, hardened seals, or holes in seals (polymer material) 12 2 9 3
p Tracking and flowing of polymer during hot weather 7 13 8 10 m Loose, rusted, cracked, missing, or damaged steel plates 2 5 3 2
Total 21 20 20 15
F12
Performance of Joints based on Each Category
Ranking Riding Quality Water Leakage Noise Maintenance
XJS S.S. XJS XJS & S.S.
S.S. LDI S.S. B.S.
I.A. B.S. B.S. LDI
B.S. & LDI XJS I.A. I.A.
Good
Worse I.A. LDI
F13
Overall Ranking of Joint Problems (Five-State Questionnaire)
Problem Ranking Symptom
1.1 1 Loose seal
1.2 2 Torn seal
1.5 3 Hardened seal
1.4 4 Cracked seal
1.3 5 Split seal
3 6 Accumulation of debris and imcompressible materials in the seals
5.2 7 Spalled concrete
2 8 Damage of adhesive lubricants causing separation of the joint material from the joint face
1.6 9 Holes in seal
5.1 10 Cracked concrete
9.1 11 Evidence of water leakage on the underside of the deck
4.2 12 Anchorage of the joint is damaged
9.3 13 Evidence of water leakage at the bent cap
8.1 14 Deterioration of bearings
7.2 15 Deterioration along beam ends
F14
Overall Ranking of Joint Problems (Follow-up Survey)
Problem Ranking Symptom
d 1 Cracked and spalled concrete, and rusted or exposed reinforcement steel or structural steel in the deck joints substrate
m 2 Loose, rusted, cracked, missing, or damaged steel plates, shapes, anchorage, bolts, nuts, holddown bars, and other metal components
h 3 Evidence of rotation, tilting, or settlement of joints n 4 Loose, torn, split, cracked, damaged, or hardened nosing materials
a 5 Loose, torn, split, cracked, damaged, hardened seals, or holes in seals
i 6 Incorrect joint opening and alignment k 6 Poor ridebility b 8 Damage of epoxy fillers or adhesive lubricants causing separation of the joint material from the joint face c 9 Accumulation of debris and incompressible materials in the seals p 10 Tracking and flowing of polymer during hot weather
g 11 Restriction on freedom of joint movement causing problems such as transverse movements of the deck
e 12 Evidence of water leakage on the underside of the deck or at the curbline
f 12 Evidence or noise during the passage of vehicles over the joint j 14 Deterioration along bearing areas on the pier caps and on the columns o 15 Backer rods fall off q 16 Traffic comes into contact with silicone l 17 Inadequate skid resistance
APPENDIX G Pictures of the In-State Site Visits
G1
PICTURES TAKEN IN SUMMER 1998 AND APRING 1999 FOR THE FOLLOWING JOINTS:
JOINT TYPE LOCATION BRIDGE CODE PAGE
B.S. I-465 over Fall Creek Road
I-465-123-4267B G2
FLEXCON 2000 (1) I-65 and Greenwood Road
I-65-100-55-59-B G3
FLEXCON 2000 (2) I-70 adjacent to Harding Street and Conrail
I-70-76-2385A G4
I.A. South Port Road over Little Buck Creek
I-65-104-55-64-DRA
G5
LDI I-70-76-5394B G6
MODULAR I-65 over White River I-65-118-4915C G7
PAVETECH (1) I-65 over Dr. Martin Luther King Drive
I-65-116-4913B G8
PAVETECH (2) I-65 at Clinton Street I-65-117-4914C G9
SLIDING PLATE AND TOOTH FINGER
I-70 Eastbound over Rural Street
I-70-19-2432B G10
S.S. (1) 38 Street Eastbound Lane over I-65
I-65-118-4636B G11
S.S. (2) I-74 G12
XJS (1) I-74 at east side of Indianapolis
I-74-94-4211C G13
XJS (2) I-59 near Carbon G14
G2
B.S. JOINT
G3
FLEXCON 2000 (1)
G4
FLEXCON 2000 (2)
G5
I.A. JOINT
G6
LDI JOINT
Cracks
G7
MODULAR JOINT
G8
PAVETECH JOINT (1)
G9
PAVETECH JOINT (2)
G10
SLIDING PLATE AND TOOTH FINGER JOINT
G11
S.S. JOINT (1)
G12
S.S. JOINT (2)
G13
XJS JOINT (1)
G14
XJS JOINT (2)
APPENDIX H Statistics of Joint Data in Each Indiana District
H1
Crawfordsville District (District Code: 1)
Joint Type Code Condition Quantity Percentage
Good 298 43.00% B.S. Type A Fair 317 45.74%
Poor 78 11.26% Subtotal 693 Good 81 37.16%
S.S. Type B Fair 96 44.04% Poor 41 18.81% Subtotal 218 Good 2 22.22%
Tooth Type C Fair 6 66.67% (Finger Joint) Poor 1 11.11%
Subtotal 9 Good 2 33.33%
General Tire Type D Fair 1 16.67% (Trans flex Type) Poor 3 50.00%
Subtotal 6 Good 0 0.00%
Feldspar Type E Fair 1 100.00% Poor 0 0.00% Subtotal 1 Good 10 27.03%
Sliding Steel Plate F Fair 24 64.86% Poor 3 8.11% Subtotal 37 Good 0 0.00%
Armor Type G Fair 0 0.00% (Two steel angles) Poor 3 100.00%
Subtotal 3 Good 285 91.64%
IA Type H Fair 16 5.14% Poor 10 3.22% Subtotal 311 Good 16 48.48%
Modular Type I Fair 17 51.52% Poor 0 0.00% Subtotal 33 Good 2 15.38%
Open Joint J Fair 9 69.23% Poor 2 15.38% Subtotal 13 Good 21 51.22%
Poured Dow Corning Silicone O Fair 20 48.78% Joint (wide width) Poor 0 0.00%
Subtotal 41
H2
Crawfordsville District (District Code: 1)
Joint Type Code Condition Quantity Percentage
Good 2 50.00% Poured Silicone Joint P Fair 2 50.00%
(narrow width - in old IA joints) Poor 0 0.00% Subtotal 4 Good 24 75.00%
Polymer Modified Asphalt Q Fair 5 15.63% Expansion Joint Poor 3 9.38%
Subtotal 32 Total 1401
H3
Fort Wayne District (District Code: 2)
Joint Type Code Condition Quantity Percentage
Good 201 32.47% B.S. Type A Fair 318 51.37%
Poor 100 16.16% Subtotal 619 Good 91 60.26%
S.S. Type B Fair 50 33.11% Poor 10 6.62% Subtotal 151 Good 0 0.00%
Tooth Type C Fair 0 0.00% (Finger Joint) Poor 0 0.00%
Subtotal 0 Good 0 0.00%
General Tire Type D Fair 0 0.00% (Trans flex Type) Poor 0 0.00%
Subtotal 0 Good 0 0.00%
Feldspar Type E Fair 1 100.00% Poor 0 0.00% Subtotal 1 Good 3 100.00%
Sliding Steel Plate F Fair 0 0.00% Poor 0 0.00% Subtotal 3 Good 0 0.00%
Armor Type G Fair 0 0.00% (Two steel angles) Poor 0 0.00%
Subtotal 0 Good 298 76.21%
IA Type H Fair 78 19.95% Poor 15 3.84% Subtotal 391 Good 1 20.00%
Modular Type I Fair 4 80.00% Poor 0 0.00% Subtotal 5 Good 0 0.00%
Open Joint J Fair 0 0.00% Poor 6 100.00% Subtotal 6 Good 10 100.00%
Poured Dow Corning Silicone O Fair 0 0.00% Joint (wide width) Poor 0 0.00%
Subtotal 10
H4
Fort Wayne District (District Code: 2)
Joint Type Code Condition Quantity Percentage
Good 8 80.00% Poured Silicone Joint P Fair 1 10.00%
(narrow width - in old IA joints) Poor 1 10.00% Subtotal 10 Good 5 100.00%
Polymer Modified Asphalt Q Fair 0 0.00% Expansion Joint Poor 0 0.00%
Subtotal 5 Total 1201
H5
Greenfield District (District Code: 3)
Joint Type Code Condition Quantity Percentage
Good 17 1.77% B.S. Type A Fair 161 16.77%
Poor 782 81.46% Subtotal 960 Good 164 72.89%
S.S. Type B Fair 20 8.89% Poor 41 18.22% Subtotal 225 Good 3 15.79%
Tooth Type C Fair 12 63.16% (Finger Joint) Poor 4 21.05%
Subtotal 19 Good 0 0.00%
General Tire Type D Fair 0 0.00% (Trans flex Type) Poor 4 100.00%
Subtotal 4 Good 0 0.00%
Feldspar Type E Fair 0 0.00% Poor 0 0.00% Subtotal 0 Good 16 72.73%
Sliding Steel Plate F Fair 5 22.73% Poor 1 4.55% Subtotal 22 Good 0 0.00%
Armor Type G Fair 0 0.00% (Two steel angles) Poor 11 100.00%
Subtotal 11 Good 166 36.24%
IA Type H Fair 169 36.90% Poor 123 26.86% Subtotal 458 Good 4 100.00%
Modular Type I Fair 0 0.00% Poor 0 0.00% Subtotal 4 Good 3 18.75%
Open Joint J Fair 4 25.00% Poor 9 56.25% Subtotal 16 Good 13 81.25%
Poured Dow Corning Silicone O Fair 1 6.25% Joint (wide width) Poor 2 12.50%
Subtotal 16
H6
Greenfield District (District Code: 3)
Joint Type Code Condition Quantity Percentage
Good 29 61.70% Poured Silicone Joint P Fair 9 19.15%
(narrow width - in old IA joints) Poor 9 19.15% Subtotal 47 Good 28 22.58%
Polymer Modified Asphalt Q Fair 42 33.87% Expansion Joint Poor 54 43.55%
Subtotal 124 Total 1906
H7
La Porte District (District Code: 4)
Joint Type Code Condition Quantity Percentage
Good 330 56.60% B.S. Type A Fair 165 28.30%
Poor 88 15.09% Subtotal 583 Good 141 71.57%
S.S. Type B Fair 36 18.27% Poor 20 10.15% Subtotal 197 Good 3 60.00%
Tooth Type C Fair 0 0.00% (Finger Joint) Poor 2 40.00%
Subtotal 5 Good 6 31.58%
General Tire Type D Fair 7 36.84% (Trans flex Type) Poor 6 31.58%
Subtotal 19 Good 0 0.00%
Feldspar Type E Fair 0 0.00% Poor 0 0.00% Subtotal 0 Good 24 100.00%
Sliding Steel Plate F Fair 0 0.00% Poor 0 0.00% Subtotal 24 Good 0 0.00%
Armor Type G Fair 17 94.44% (Two steel angles) Poor 1 5.56%
Subtotal 18 Good 274 87.82%
IA Type H Fair 36 11.54% Poor 2 0.64% Subtotal 312 Good 11 64.71%
Modular Type I Fair 6 35.29% Poor 0 0.00% Subtotal 17 Good 7 41.18%
Open Joint J Fair 8 47.06% Poor 2 11.76% Subtotal 17 Good 21 63.64%
Poured Dow Corning Silicone O Fair 12 36.36% Joint (wide width) Poor 0 0.00%
Subtotal 33
H8
La Porte District (District Code: 4)
Joint Type Code Condition Quantity Percentage
Good 26 68.42% Poured Silicone Joint P Fair 11 28.95%
(narrow width - in old IA joints) Poor 1 2.63% Subtotal 38 Good 34 89.47%
Polymer Modified Asphalt Q Fair 4 10.53% Expansion Joint Poor 0 0.00%
Subtotal 38 Total 1301
H9
Seymour District (District Code: 5)
Joint Type Code Condition Quantity Percentage
Good 427 63.07% B.S. Type A Fair 198 29.25%
Poor 52 7.68% Subtotal 677 Good 92 66.19%
S.S. Type B Fair 33 23.74% Poor 14 10.07% Subtotal 139 Good 3 9.38%
Tooth Type C Fair 29 90.63% (Finger Joint) Poor 0 0.00%
Subtotal 32 Good 1 12.50%
General Tire Type D Fair 4 50.00% (Trans flex Type) Poor 3 37.50%
Subtotal 8 Good 0 0.00%
Feldspar Type E Fair 1 100.00% Poor 0 0.00% Subtotal 1 Good 1 4.35%
Sliding Steel Plate F Fair 22 95.65% Poor 0 0.00% Subtotal 23 Good 0 0.00%
Armor Type G Fair 3 60.00% (Two steel angles) Poor 2 40.00%
Subtotal 5 Good 181 76.05%
IA Type H Fair 16 6.72% Poor 41 17.23% Subtotal 238 Good 9 81.82%
Modular Type I Fair 1 9.09% Poor 1 9.09% Subtotal 11 Good 15 27.78%
Open Joint J Fair 38 70.37% Poor 1 1.85% Subtotal 54 Good 10 100.00%
Poured Dow Corning Silicone O Fair 0 0.00% Joint (wide width) Poor 0 0.00%
Subtotal 10
H10
Seymour District (District Code: 5)
Joint Type Code Condition Quantity Percentage
Good 0 0.00% Poured Silicone Joint P Fair 0 0.00%
(narrow width - in old IA joints) Poor 0 0.00% Subtotal 0 Good 42 100.00%
Polymer Modified Asphalt Q Fair 0 0.00% Expansion Joint Poor 0 0.00%
Subtotal 42 Total 1240
H11
Vincennes District (District Code: 6)
Joint Type Code Condition Quantity Percentage
Good 137 27.24% B.S. Type A Fair 273 54.27%
Poor 93 18.49% Subtotal 503 Good 125 68.68%
S.S. Type B Fair 44 24.18% Poor 13 7.14% Subtotal 182 Good 2 15.38%
Tooth Type C Fair 6 46.15% (Finger Joint) Poor 5 38.46%
Subtotal 13 Good 0 0.00%
General Tire Type D Fair 4 66.67% (Trans flex Type) Poor 2 33.33%
Subtotal 6 Good 0 0.00%
Feldspar Type E Fair 2 100.00% Poor 0 0.00% Subtotal 2 Good 1 16.67%
Sliding Steel Plate F Fair 5 83.33% Poor 0 0.00% Subtotal 6 Good 0 0.00%
Armor Type G Fair 0 0.00% (Two steel angles) Poor 17 100.00%
Subtotal 17 Good 231 73.80%
IA Type H Fair 76 24.28% Poor 6 1.92% Subtotal 313 Good 15 71.43%
Modular Type I Fair 3 14.29% Poor 3 14.29% Subtotal 21 Good 0 0.00%
Open Joint J Fair 28 80.00% Poor 7 20.00% Subtotal 35 Good 18 58.06%
Poured Dow Corning Silicone O Fair 12 38.71% Joint (wide width) Poor 1 3.23%
Subtotal 31
H12
Vincennes District (District Code: 6)
Joint Type Code Condition Quantity Percentage
Good 8 100.00% Poured Silicone Joint P Fair 0 0.00%
(narrow width - in old IA joints) Poor 0 0.00% Subtotal 8 Good 35 66.04%
Polymer Modified Asphalt Q Fair 11 20.75% Expansion Joint Poor 7 13.21%
Subtotal 53 Total 1190
APPENDIX I
Computer SAS Code and Output of Regression Analysis
I1
SAS Code (Use B.S. Joint (Type A) as an example) var age adt dw brw sl lms sma scn ama acn sbr sim sbs ins; title 'Joint A with all variables'; run; proc score data=swa score=fact out=scores; (factor analysis) run; proc logistic data=scores; (logistic regression) model cond= factor1 factor2 factor3 age /selection = stepwise slentry=0.1 slstay=0.1 details; /*output out=pred p=phat lower=lcl upper=ucl;*/ run; /*proc print data=pred; run;*/ SAS Output Joint A with all variables 453 20:09 Tuesday, September 28, 1999 Means and Standard Deviations from 1274 observations ADT AGE DW BRW SL Mean 14849.3399 11.5816327 47.9065934 43.7174254 221.320251 Std Dev 19724.0413 5.58192644 18.701397 17.9636159 181.966584 LMS SMA SCN AMA CAN Mean 68.9348509 4.02904239 2.23233909 0.37912088 0.42935636 Std Dev 24.6822317 1.21973992 1.25881889 0.96354796 0.87477618 SBR SIM SBS INS Mean 6.89638932 7.09340659 7.40973312 7.45368917 Std Dev 0.86764455 0.74990684 0.61540789 0.60747353 Kaiser's Measure of Sampling Adequacy: Over-all MSA = 0.68891944 ADT AGE DW BRW SL LMS SMA 0.916612 0.840510 0.584397 0.578267 0.690589 0.695165 0.731025 SCN AMA CAN SBR SIM SBS INS 0.654124 0.632429 0.613991 0.813145 0.829929 0.696926 0.696977 Prior Communality Estimates: ONE Eigenvalues of the Correlation Matrix: Total = 14 Average = 1 1 2 3 4 5 Eigenvalue 3.3403 2.6597 2.3675 0.9852 0.9029 Difference 0.6806 0.2922 1.3823 0.0823 0.0846 Proportion 0.2386 0.1900 0.1691 0.0704 0.0645 Cumulative 0.2386 0.4286 0.5977 0.6681 0.7326 Joint A with all variables 455 20:09 Tuesday, September 28, 1999 Initial Factor Method: Principal Components 6 7 8 9 10 Eigenvalue 0.8184 0.7797 0.6247 0.4680 0.3647 Difference 0.0387 0.1550 0.1567 0.1032 0.0350
I2
Proportion 0.0585 0.0557 0.0446 0.0334 0.0261 Cumulative 0.7910 0.8467 0.8913 0.9247 0.9508 11 12 13 14 Eigenvalue 0.3298 0.2115 0.1370 0.0107 Difference 0.1183 0.0745 0.1263 Proportion 0.0236 0.0151 0.0098 0.0008 Cumulative 0.9743 0.9895 0.9992 1.0000 3 factors will be retained by the MINEIGEN criterion. Joint A with all variables 456 20:09 Tuesday, September 28, 1999 Initial Factor Method: Principal Components Scree Plot of Eigenvalues ‚ ‚ 3.5 ˆ ‚ ‚ 1 ‚ ‚ ‚ ‚ 3.0 ˆ ‚ ‚ ‚ ‚ ‚ 2 ‚ 2.5 ˆ ‚ ‚ 3 ‚ ‚ E ‚ i ‚ g 2.0 ˆ e ‚ n ‚ v ‚ a ‚ l ‚ u ‚ e 1.5 ˆ s ‚ ‚ ‚ ‚ ‚ ‚ 1.0 ˆ 4 ‚ 5 ‚ ‚ 6 7 ‚ ‚ 8 ‚ 0.5 ˆ 9 ‚ ‚ 0 1 ‚ ‚ 2 ‚ 3
I3
‚ 0.0 ˆ 4 ‚ Šƒƒƒƒˆƒƒƒƒˆƒƒƒƒˆƒƒƒƒˆƒƒƒƒˆƒƒƒƒˆƒƒƒƒˆƒƒƒƒˆƒƒƒƒˆƒƒƒƒˆƒƒƒƒˆƒƒƒƒˆƒƒƒƒˆƒƒƒƒˆƒƒƒƒˆƒƒƒƒƒ 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 Number Joint A with all variables 457 20:09 Tuesday, September 28, 1999 Initial Factor Method: Principal Components Factor Pattern FACTOR1 FACTOR2 FACTOR3 Settlement Traffic Loading Structure Design ADT -0.23364 0.80439 0.19771 ADT AGE -0.39460 -0.12404 -0.18757 AGE DW 0.00931 0.88434 0.38131 DW BRW 0.03581 0.89491 0.37440 BRW SL -0.32583 -0.27922 0.56094 SL LMS -0.29728 -0.19205 0.63716 LMS SMA 0.48948 0.02074 0.22146 SMA SCN -0.13433 -0.24543 0.42754 SCN AMA -0.42908 -0.27850 0.68870 AMA CAN -0.46627 -0.30319 0.53205 CAN SBR 0.73583 -0.06501 0.29247 SBR SIM 0.70328 -0.21381 0.21736 SIM SBS 0.79118 -0.09688 0.27852 SBS INS 0.78290 -0.10027 0.29581 INS Variance explained by each factor FACTOR1 FACTOR2 FACTOR3 3.340301 2.659723 2.367544 Final Communality Estimates: Total = 8.367568 ADT AGE DW BRW SL LMS SMA 0.740728 0.206275 0.927535 0.942318 0.498779 0.531224 0.289068 SCN AMA CAN SBR SIM SBS INS 0.261069 0.735979 0.592409 0.631210 0.587566 0.712920 0.710486 Joint A with all variables 458 20:09 Tuesday, September 28, 1999 Rotation Method: Varimax Orthogonal Transformation Matrix 1 2 3 1 0.91091 -0.07936 -0.40491 2 -0.08005 0.92869 -0.36211 3 0.40477 0.36227 0.83960 Rotated Factor Pattern FACTOR1 FACTOR2 FACTOR3 ADT -0.19719 0.83720 -0.03068 ADT AGE -0.42543 -0.15183 0.04721 AGE
I4
DW 0.09203 0.95867 -0.00385 DW BRW 0.11253 0.96388 -0.02421 BRW SL -0.04740 -0.03024 0.70400 SL LMS 0.00248 0.07606 0.72487 LMS SMA 0.53385 0.06065 -0.01977 SMA SCN 0.07034 -0.06238 0.50222 SCN AMA -0.08979 0.02490 0.85282 AMA CAN -0.18510 -0.05182 0.74529 CAN SBR 0.79386 -0.01282 -0.02884 SBR SIM 0.74572 -0.17563 -0.02485 SIM SBS 0.84118 -0.05186 -0.05143 SBS INS 0.84091 -0.04809 -0.03233 INS Variance explained by each factor FACTOR1 FACTOR2 FACTOR3 3.176564 2.625664 2.565339 Final Communality Estimates: Total = 8.367568 ADT AGE DW BRW SL LMS SMA 0.740728 0.206275 0.927535 0.942318 0.498779 0.531224 0.289068 SCN AMA CAN SBR SIM SBS INS 0.261069 0.735979 0.592409 0.631210 0.587566 0.712920 0.710486 Scoring Coefficients Estimated by Regression Squared Multiple Correlations of the Variables with each Factor FACTOR1 FACTOR2 FACTOR3 1.000000 1.000000 1.000000 Joint A with all variables 459 20:09 Tuesday, September 28, 1999 Rotation Method: Varimax Standardized Scoring Coefficients FACTOR1 FACTOR2 FACTOR3 ADT -0.05412 0.31667 -0.01108 ADT AGE -0.13594 -0.06264 -0.00180 AGE DW 0.04111 0.36691 0.01370 DW BRW 0.04684 0.36891 0.00659 BRW SL 0.01545 -0.00392 0.27644 SL LMS 0.03364 0.03750 0.28814 LMS SMA 0.17072 0.02950 0.01638 SMA SCN 0.04385 -0.01709 0.20131 SCN AMA 0.00912 0.01833 0.33416 AMA CAN -0.02707 -0.01338 0.28648 CAN SBR 0.25262 0.00457 0.02337 SBR SIM 0.23538 -0.05810 0.02094 SIM SBS 0.26629 -0.01001 0.01605 SBS INS 0.26709 -0.00835 0.02365 INS Joint A with all variables 460 20:09 Tuesday, September 28, 1999 The LOGISTIC Procedure Data Set: WORK.SCORES Response Variable: COND COND Response Levels: 2 Number of Observations: 1274 Link Function: Logit
I5
Response Profile Ordered Value COND2 Count 1 G 841 2 P 433 WARNING: 530 observation(s) were deleted due to missing values for the response or explanatory variables. Stepwise Selection Procedure Step 0. Intercept entered: Analysis of Maximum Likelihood Estimates Parameter Standard Wald Pr > Standardized Odds Variable Variable DF Estimate Error Chi-Square Chi-Square Estimate Ratio Label INTERCPT 1 0.6639 0.0591 125.9678 0.0001 . . Intercept Residual Chi-Square = 379.2337 with 6 DF (p=0.0001) Analysis of Variables Not in the Model Score Pr > Variable Variable Chi-Square Chi-Square Label FACTOR1 297.7141 0.0001 FACTOR2 39.0210 0.0001 FACTOR3 8.4209 0.0037 AGE 118.5574 0.0001 AGE Step 1. Variable FACTOR1 entered: Joint A with all variables 461 20:09 Tuesday, September 28, 1999 The LOGISTIC Procedure Model Fitting Information and Testing Global Null Hypothesis BETA=0 Intercept Intercept and Criterion Only Covariates Chi-Square for Covariates AIC 1635.146 1234.006 . SC 1640.296 1244.306 . -2 LOG L 1633.146 1230.006 403.140 with 1 DF (p=0.0001) Score . . 297.714 with 1 DF (p=0.0001) Analysis of Maximum Likelihood Estimates Parameter Standard Wald Pr > Standardized Odds Variable Variable DF Estimate Error Chi-Square Chi-Square Estimate Ratio Label INTERCPT 1 1.1538 0.0892 167.1429 0.0001 . . Intercept FACTOR1 1 1.8588 0.1280 210.7571 0.0001 1.024819 6.416
I6
Association of Predicted Probabilities and Observed Responses Concordant = 83.2% Somers' D = 0.665 Discordant = 16.7% Gamma = 0.666 Tied = 0.2% Tau-a = 0.299 (364153 pairs) c = 0.832 Residual Chi-Square = 87.6357 with 5 DF (p=0.0001) Analysis of Variables Not in the Model Score Pr > Variable Variable Chi-Square Chi-Square Label FACTOR2 45.0365 0.0001 FACTOR3 11.8221 0.0006 AGE 11.9715 0.0005 AGE Step 2. Variable FACTOR2 entered: Joint A with all variables 462 20:09 Tuesday, September 28, 1999 The LOGISTIC Procedure Model Fitting Information and Testing Global Null Hypothesis BETA=0 Intercept Intercept and Criterion Only Covariates Chi-Square for Covariates AIC 1635.146 1189.409 . SC 1640.296 1204.859 . -2 LOG L 1633.146 1183.409 449.737 with 2 DF (p=0.0001) Score . . 336.735 with 2 DF (p=0.0001) Analysis of Maximum Likelihood Estimates Parameter Standard Wald Pr > Standardized Odds Variable Variable DF Estimate Error Chi-Square Chi-Square Estimate Ratio Label INTERCPT 1 1.1760 0.0918 164.1834 0.0001 . . Intercept FACTOR1 1 1.9188 0.1323 210.4439 0.0001 1.057877 6.813 FACTOR2 1 -0.4921 0.0758 42.1413 0.0001 -0.271296 0.611 Association of Predicted Probabilities and Observed Responses Concordant = 84.8% Somers' D = 0.698 Discordant = 15.0% Gamma = 0.699 Tied = 0.2% Tau-a = 0.313 (364153 pairs) c = 0.849 Residual Chi-Square = 44.1219 with 4 DF (p=0.0001) Analysis of Variables Not in the Model Score Pr > Variable Variable Chi-Square Chi-Square Label FACTOR3 9.7092 0.0018 AGE 24.9274 0.0001 AGE
I7
Step 3. Variable AGE entered: Joint A with all variables 463 20:09 Tuesday, September 28, 1999 The LOGISTIC Procedure Model Fitting Information and Testing Global Null Hypothesis BETA=0 Intercept Intercept and Criterion Only Covariates Chi-Square for Covariates AIC 1635.146 1166.252 . SC 1640.296 1186.851 . -2 LOG L 1633.146 1158.252 474.894 with 3 DF (p=0.0001) Score . . 362.134 with 3 DF (p=0.0001) Analysis of Maximum Likelihood Estimates Parameter Standard Wald Pr > Standardized Odds Variable Variable DF Estimate Error Chi-Square Chi-Square Estimate Ratio Label INTERCPT 1 1.9820 0.1923 106.2525 0.0001 . . Intercept FACTOR1 1 1.7396 0.1346 167.0665 0.0001 0.959071 3.120 FACTOR2 1 -0.5784 0.0807 51.3845 0.0001 -0.318914 0.651 AGE 1 -0.0701 0.0143 24.1740 0.0001 -0.215838 0.805 AGE Association of Predicted Probabilities and Observed Responses Concordant = 85.2% Somers' D = 0.706 Discordant = 14.7% Gamma = 0.706 Tied = 0.1% Tau-a = 0.317 (364153 pairs) c = 0.853 Residual Chi-Square = 19.0387 with 3 DF (p=0.0003) Analysis of Variables Not in the Model Score Pr > Variable Variable Chi-Square Chi-Square Label FACTOR3 12.3739 0.3 NOTE: No (additional) variables met the 0.1 significance level for entry into the model. Joint A with all variables 466 20:09 Tuesday, September 28, 1999 The LOGISTIC Procedure Summary of Stepwise Procedure Variable Number Score Wald Pr > Variable Step Entered Removed In Chi-Square Chi-Square Chi-Square Label 1 FACTOR1 1 297.7 . 0.0001 2 FACTOR2 2 45.0365 . 0.0001 3 AGE 3 24.9274 . 0.0001 AGE
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